Methods of using improved polymerases

ABSTRACT

This invention provides for methods of sequencing and performing polymerase reactions using an improved generation of nucleic acid polymerases. The improvement is the fusion of a sequence-non-specific nucleic-acid-binding domain to the enzyme in a manner that enhances the processivity of the polymerase.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application claims the benefit of U.S. provisional application No. 60/333,966, filed Nov. 28, 2001, which is incorporated by reference herein.

FIELD OF THE INVENTION

This invention provides more efficient methods of performing polymerase reactions. The methods employ an improved generation of nucleic acid polymerases. The improvement is the joining sequence-non-specific nucleic-acid-binding domain to the enzyme in a manner that enhances the ability of the enzyme to bind and catalytically modify the nucleic acid.

BACKGROUND OF THE INVENTION

The processivity of a polymerase, i.e., the amount of product generated by the enzyme per binding event, can be enhanced by increasing the stability of the modifying enzyme/nucleic acid complex. The current invention now provides enhanced polymerase assays that employ novel modifying enzymes in which the double-stranded conformation of the nucleic acid is stabilized and the processivity of the enzyme increased by joining a sequence-non-specific double-stranded nucleic acid binding domain to the enzyme, or its catalytic domain which are disclosed e.g., in co-pending U.S. application Ser. No. 09/870,353 and WO01/92501. The modifying proteins that are processive in nature exhibit increased processivity when joined to a binding domain compared to the enzyme alone.

There is a need to enhance polymerase reactions in many applications. For example, SYBR Green I (Molecular Probes, Eugene, Oreg.; U.S. Pat. Nos. 5,436,134 and 5,658,751), a fluorescent dye that is specific for dsDNA detection, is widely used in real-time PCR reactions to monitor the generation of dsDNA through each cycle of amplification. However, the addition of SYBR Green I inhibits the activity of DNA polymerases used in PCR. Similarly, it is often desirable to use PCR for the analysis of crude or “dirty” nucleic acid samples. For example, colony PCR is a useful technique in which small samples of single bacterial colonies are lysed and added directly to PCR reactions for the purpose of screening colonies for particular DNA sequences. However, colony PCR has a high failure rate, because of residual contaminants from the colony. Thus, polymerases that are resistant to such inhibitors, e.g., fluorescent dyes and impurities present in the cell extracts, are needed in order to obtain more efficient polymerase reactions, e.g., PCR.

There is also a need to improve sequencing reactions. Polymerases currently employed in sequencing reactions, e.g., cycle sequencing, are often inefficient. For example, cycle sequencing is often performed with poorly-processive enzymes. Often, the enzymes used are ΔTaq derivatives, which have Taq polymerase's 5′-3′ nuclease domain removed, and have a processivity of about 2 bases. Also, in the case of dye terminator-sequencing, dITP is used in place of dGTP, which causes polymerase pausing and dissociation at G nucleotides. These enzymes therefore produce a large number of sequence products that are improperly terminated. These stops compete with, and negatively effect, the production of properly terminated sequence products. Furthermore, if a polymerase dissociates during primer extension of a template containing a repeat unit (e.g., a triplet repeat) or secondary structure (e.g., a stem and loop), the 3′ end can denature and reanneal so as to prime at a different location on the template—for example, in the case of a repeat, the reannealing could occur at a different repeat; or in the case of secondary structure, improper reannealing could delete out a section of the template. Thus, dissociation of the polymerase during sequencing can cause a problem in efficiently obtaining reliable sequencing information.

The current invention addresses both of these needs, i.e., the need for enhancing polymerase reactions performed in the presence of inhibitors and the need for enhancing processivity in DNA sequencing applications). The current invention provides such enhanced, or improved, polymerase reactions. The improvement is the use of a polymerase that has increased processivity due to the presence of a sequence-non-specific nucleic-acid-binding domain that is joined to the polymerase.

BRIEF SUMMARY OF THE INVENTION

The present invention provides methods of performing more efficient polymerase reactions using a polymerase protein comprising a polymerase domain joined to a sequence-non-specific double-stranded nucleic acid binding domain. Typically the presence of the sequence non-specific double-stranded nucleic acid binding domain enhances the processivity of the polymerase compared to an identical protein not having a sequence-non-specific nucleic acid binding domain joined thereto.

The polymerase domain can be thermally stable, e.g., a Thermus polymerase domain such as a ΔTaq polymerase domain, or a Pyrococcus polymerase domain.

In one embodiment the sequence-non-specific nucleic-acid-binding domain specifically binds to polyclonal antibodies generated against either Sac7d or Sso7d. Alternatively, the sequence-non-specific nucleic-acid-binding domain contains a 50 amino acid subsequence containing 50% amino acid similarity to Sso7d. Typically, the sequence-non-specific nucleic-acid-binding domain is Sso7d or specifically binds to polyclonal antibodies generated against Sso7d.

The polymerase reaction can be performed on a target nucleic acid that is present in a crude preparation of a sample. In another embodiment, the polymerase reaction is performed in the presence of a molecule that typically inhibits polymerases, e.g. fluorescent dyes such as SYBR Green I. Further, the polymerase may be used in cycle sequencing reactions to obtain longer sequences, e.g., through regions of secondary structure that prevent sequencing using unmodified polymerases.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B show the results of a PCR reaction performed in the presence of contaminants using an improved polymerase.

DETAILED DESCRIPTION OF THE INVENTION

Definitions

“Archaeal small basic DNA-binding protein” refers to protein of between 50-75 amino acids having either 50% homology to a natural Archaeal small basic DNA-binding protein such as Sso-7d from Sulfolobus sulfataricus or binds to antibodies generated against a native Archaeal small basic DNA-binding protein.

“Domain” refers to a unit of a protein or protein complex, comprising a polypeptide subsequence, a complete polypeptide sequence, or a plurality of polypeptide sequences where that unit has a defined function. The function is understood to be broadly defined and can be ligand binding, catalytic activity or can have a stabilizing effect on the structure of the protein.

“Efficiency” in the context of a nucleic acid modifying enzyme of this invention refers to the ability of the enzyme to perform its catalytic function under specific reaction conditions. Typically, “efficiency” as defined herein is indicated by the amount of product generated under given reaction conditions.

“Enhances” in the context of an enzyme refers to improving the activity of the enzyme, i.e., increasing the amount of product per unit enzyme per unit time.

“Fused” refers to linkage by covalent bonding.

“Heterologous”, when used with reference to portions of a protein, indicates that the protein comprises two or more domains that are not found in the same relationship to each other in nature. Such a protein, e.g., a fusion protein, contains two or more domains from unrelated proteins arranged to make a new functional protein.

“Join” refers to any method known in the art for functionally connecting protein domains, including without limitation recombinant fusion with or without intervening domains, intein-mediated fusion, non-covalent association, and covalent bonding, including disulfide bonding; hydrogen bonding; electrostatic bonding; and conformational bonding, e.g., antibody-antigen, and biotin-avidin associations.

“Nucleic-acid-modifying enzyme” refers to an enzyme that covalently alters a nucleic acid.

“Polymerase” refers to an enzyme that performs template-directed synthesis of polynucleotides. The term, as used herein, also refers to a domain of the polymerase that has catalytic activity.

“Error-correcting activity” of a polymerase or polymerase domain refers to the 3′ to 5′ exonuclease proofreading activity of a template-specific nucleic acid polymerase whereby nucleotides that do not form Watson-Crick base pairs with the template are removed from the 3′ end of an oligonucleotide, i.e., a strand being synthesized from a template, in a sequential manner. Examples of polymerases that have error-correcting activity include polymerases from Pryococcus furiosus, Thermococcus litoralis, and Thermotoga maritima.

Processivity refers to the ability of a nucleic acid modifying enzyme to remain bound to the template or substrate and perform multiple modification reactions. Processivity is measured by the number of catalytic events that take place per binding event.

“Sequence-non-specific nucleic-acid-binding domain” refers to a protein domain which binds with significant affinity to a nucleic acid, for which there is no known nucleic acid which binds to the protein domain with more than 100-fold more affinity than another nucleic acid with the same nucleotide composition but a different nucleotide sequence.

“Thermally stable polymerase” as used herein refers to any enzyme that catalyzes polynucleotide synthesis by addition of nucleotide units to a nucleotide chain using DNA or RNA as a template and has an optimal activity at a temperature above 45° C.

“Thermus polymerase” refers to a family A DNA polymerase isolated from any Thermus species, including without limitation Thermus aquaticus, Thermus brockianus, and Thermus thermophilus; any recombinant enzymes deriving from Thermus species, and any functional derivatives thereof, whether derived by genetic modification or chemical modification or other methods known in the art.

The term “amplification reaction” refers to any in vitro means for multiplying the copies of a target sequence of nucleic acid. Such methods include but are not limited to polymerase chain reaction (PCR), DNA ligase reaction (see U.S. Pat. Nos. 4,683,195 and 4,683,202; PCR Protocols: A Guide to Methods and Applications (Innis et al., eds, 1990)), (LCR), QBeta RNA replicase, and RNA transcription-based (such as TAS and 3SR) amplification reactions as well as others known to those of skill in the art.

“Amplifying” refers to a step of submitting a solution to conditions sufficient to allow for amplification of a polynucleotide if all of the components of the reaction are intact. Components of an amplification reaction include, e.g., primers, a polynucleotide template, polymerase, nucleotides, and the like. The term “amplifying” typically refers to an “exponential” increase in target nucleic acid. However, “amplifying” as used herein can also refer to linear increases in the numbers of a select target sequence of nucleic acid.

The term “amplification reaction mixture” refers to an aqueous solution comprising the various reagents used to amplify a target nucleic acid. These include enzymes, aqueous buffers, salts, amplification primers, target nucleic acid, and nucleoside triphosphates. Depending upon the context, the mixture can be either a complete or incomplete amplification reaction mixture

“Polymerase chain reaction” or “PCR” refers to a method whereby a specific segment or subsequence of a target double-stranded DNA, is amplified in a geometric progression. PCR is well known to those of skill in the art; see, e.g., U.S. Pat. Nos. 4,683,195 and 4,683,202; and PCR Protocols: A Guide to Methods and Applications, Innis et al., eds, 1990. Exemplary PCR reaction conditions typically comprise either two or three step cycles. Two step cycles have a denaturation step followed by a hybridization/elongation step. Three step cycles comprise a denaturation step followed by a hybridization step followed by a separate elongation step.

“Long PCR” refers to the amplification of a DNA fragment of 5 kb or longer in length. Long PCR is typically performed using specially-adapted polymerases or polymerase mixtures (see, e.g., U.S. Pat. Nos. 5, 436,149 and 5,512,462) that are distinct from the polymerases conventionally used to amplify shorter products.

A “primer” refers to a polynucleotide sequence that hybridizes to a sequence on a target nucleic acid and serves as a point of initiation of nucleic acid synthesis. Primers can be of a variety of lengths and are often less than 50 nucleotides in length, for example 12-30 nucleotides, in length. The length and sequences of primers for use in PCR can be designed based on principles known to those of skill in the art, see, e.g., Innis et al., supra.

A temperature profile refers to the temperature and lengths of time of the denaturation, annealing and/or extension steps of a PCR or cycle sequencing reaction. A temperature profile for a PCR or cycle sequencing reaction typically consists of 10 to 60 repetitions of similar or identical shorter temperature profiles; each of these shorter profiles may typically define a two step or three-step cycle. Selection of a temperature profile is based on various considerations known to those of skill in the art, see, e.g., Innis et al., supra. In a long PCR reaction as described herein, the extension time required to obtain an amplification product of 5 kb or greater in length is reduced compared to conventional polymerase mixtures.

PCR “sensitivity” refers to the ability to amplify a target nucleic acid that is present in low copy number. “Low copy number” refers to 10⁵, often 10⁴, 10³, 10², or fewer, copies of the target sequence in the nucleic acid sample to be amplified.

A “template” refers to a double stranded polynucleotide sequence that comprises the polynucleotide to be amplified, flanked by primer hybridization sites. Thus, a “target template” comprises the target polynucleotide sequence flanked by hybridization sites for a 5′ primer and a 3′ primer.

An “improved polymerase” includes a sequence-non-specific double-stranded DNA binding domain joined to the polymerase or polymerase domain. An “unimproved polymerase” is a polymerase that does not have a sequence-non-specific double-stranded DNA binding domain.

Introduction

The current invention provides methods of performing polymerase reactions using improved polymerases. These polymerase reactions are typically more efficient and yield more product than traditional polymerases. These improved polymerases contain a polymerase domain with a binding domain joined to it. While the prior art taught that nucleic acid binding proteins can increase the binding affinity of enzymes to nucleic acid, the group of binding proteins having the ability to enhance the processive nature of the enzymes is of particular value. Not to be bound by theory, binding domains of the invention typically dissociate from double-stranded nucleic acid at a very slow rate. Thus, they increase the processivity and/or efficiency of a modifying enzyme to which they are joined by stabilizing the enzyme-nucleic acid complex. Accordingly, this invention results from the discovery that DNA-binding domains can stabilize the double-stranded conformation of a nucleic acid and increase the efficiency of a catalytic domain that requires a double-stranded substrate. Described herein are examples and simple assays to readily determine the improvement to the catalytic and/or processive nature of catalytic nucleic acid modifying enzymes, e.g., polymerases.

Polymerase Domains.

DNA polymerases are well-known to those skilled in the art. These include both DNA-dependent polymerases and RNA-dependent polymerases such as reverse transcriptase. At least five families of DNA-dependent DNA polymerases are known, although most fall into families A, B and C. There is little or no structural or sequence similarity among the various families. Most family A polymerases are single chain proteins that can contain multiple enzymatic functions including polymerase, 3′ to 5′ exonuclease activity and 5′ to 3′ exonuclease activity. Family B polymerases typically have a single catalytic domain with polymerase and 3′ to 5′ exonuclease activity, as well as accessory factors. Family C polymerases are typically multi-subunit proteins with polymerizing and 3′ to 5′ exonuclease activity. In E. coli, three types of DNA polymerases have been found, DNA polymerases I (family A), II (family B), and III (family C). In eukaryotic cells, three different family B polymerases, DNA polymerases α, δ, and ε, are implicated in nuclear replication, and a family A polymerase, polymerase γ, is used for mitochondrial DNA replication. Other types of DNA polymerases include phage polymerases.

Similarly, RNA polymerases typically include eukaryotic RNA polymerases I, II, and III, and bacterial RNA polymerases as well as phage and viral polymerases. RNA polymerases can be DNA-dependent and RNA-dependent.

In one embodiment, polymerase domains that have an error-correcting activity are used as the catalytic domain of the improved polymerases described herein. These polymerases can be used to obtain long, i.e., 5 kb, often 10 kb, or greater in length, PCR products. “Long PCR” using these improved polymerases can be performed using extension times that are reduced compared to prior art “long PCR” polymerase and/or polymerase mixtures. Extension times of less than 30 seconds per kb, often 15 seconds per kb, can be used to amplify long products in PCR reactions using the improved polymerases. Furthermore, these modified polymerases also exhibit increased sensitivity.

Prior-art non-error-correcting polymerases such as Taq polymerase are capable of amplifying DNA from very small input copy concentrations, such as, in the extreme, 10 copies per ml. However, because of the low fidelity of such polymerases, products cloned from such amplifications are likely to contain introduced mutations.

Prior-art error-correcting polymerases such as Pfu copy DNA with higher fidelity than Taq, but are not capable of amplifying DNA from small input copy concentrations. The hybrid error-correcting polymerases of the invention exhibit much higher processivity while retaining error-correcting activity and thereby provide both sensitivity and fidelity in amplification reactions.

The activity of a polymerase can be measured using assays well known to those of skill in the art. For example, a processive enzymatic activity, such as a polymerase activity, can be measured by determining the amount of nucleic acid synthesized in a reaction, such as a polymerase chain reaction. In determining the relative efficiency of the enzyme, the amount of product obtained with a polymerase containing a sequence-non-specific double-stranded DNA binding domain can then be compared to the amount of product obtained with the normal polymerase enzyme, which will be described in more detail below and in the Examples.

A polymerase domain suitable for use in the invention can be the enzyme itself or the catalytic domain, e.g., Taq polymerase or a domain of Taq with polymerase activity. The catalytic domain may include additional amino acids and/or may be a variant that contains amino acid substitutions, deletions or additions, but still retains enzymatic activity.

Sequence-Non-Specific Nucleic-Acid-Binding Domain

A double-stranded sequence-non-specific nucleic acid binding domain is a protein or defined region of a protein that binds to double-stranded nucleic acid in a sequence-independent manner, i.e., binding does not exhibit a gross preference for a particular sequence. Typically, double-stranded nucleic acid binding proteins exhibit a 10-fold or higher affinity for double-stranded versus single-stranded nucleic acids. The double-stranded nucleic acid binding proteins in particular embodiments of the invention are preferably thermostable. Examples of such proteins include, but are not limited to, the Archaeal small basic DNA binding proteins Sac7d and Sso7d (see, e.g., Choli et al., Biochimica et Biophysica Acta 950:193-203, 1988; Baumann et al., Structural Biol. 1:808-819, 1994; and Gao et al, Nature Struc. Biol. 5:782-786, 1998), Archael HMf-like proteins (see, e.g., Starich et al., J. Molec. Biol. 255:187-203, 1996; Sandman et al., Gene 150:207-208, 1994), and PCNA homologs (see, e.g., Cann et al., J. Bacteriology 181:6591-6599, 1999; Shamoo and Steitz, Cell: 99, 155-166, 1999; De Felice et al., J. Molec. Biol. 291, 47-57, 1999; and Zhang et al., Biochemistry 34:10703-10712, 1995).

Sso7d and Sac7d

Sso7d and Sac7d are small (about 7,000 kd MW), basic chromosomal proteins from the hyperthermophilic archaeabacteria Sulfolobus solfataricus and S. acidocaldarius, respectively. These proteins are lysine-rich and have high thermal, acid and chemical stability. They bind DNA in a sequence-independent manner and when bound, increase the T_(M) of DNA by up to 40° C. under some conditions (McAfee et al., Biochemistry 34:10063-10077, 1995). These proteins and their homologs are typically believed to be involved in packaging genomic DNA and stabilizing genomic DNA at elevated temperatures.

HMF-Like Proteins

The HMf-like proteins are archaeal histones that share homology both in amino acid sequences and in structure with eukaryotic H4 histones, which are thought to interact directly with DNA. The HMf family of proteins form stable dimers in solution, and several HMf homologs have been identified from thermostable species (e.g., Methanothermus fervidus and Pyrococcus strain GB-3a). The HMf family of proteins, once joined to Taq DNA polymerase or any DNA modifying enzyme with a low intrinsic processivity, can enhance the ability of the enzyme to slide along the DNA substrate and thus increase its processivity. For example, the dimeric HMf-like protein can be covalently linked to the N terminus of Taq DNA polymerase, e.g., via chemical modification, and thus improve the processivity of the polymerase.

PCNA Homologs

Many but not all family B DNA polymerases interact with accessory proteins to achieve highly processive DNA synthesis. A particularly important class of accessory proteins is referred to as the sliding clamp. Several characterized sliding clamps exist as trimers in solution, and can form a ring-like structure with a central passage capable of accommodating double-stranded DNA. The sliding clamp forms specific interactions with the amino acids located at the C terminus of particular DNA polymerases, and tethers those polymerases to the DNA template during replication. The sliding clamp in eukarya is referred to as the proliferating cell nuclear antigen (PCNA), while similar proteins in other domains are often referred to as PCNA homologs. These homologs have marked structural similarity but limited sequence similarity.

Recently, PCNA homologs have been identified from thermophilic Archaea (e.g., Sulfalobus sofataricus, Pyroccocus furiosus, etc.). Some family B polymerases in Archaea have a C terminus containing a consensus PCNA-interacting amino acid sequence and are capable of using a PCNA homolog as a processivity factor (see, e.g., Cann et al., J. Bacteriol. 181:6591-6599, 1999 and De Felice et al., J. Mol. Biol. 291:47-57, 1999). These PCNA homologs are useful sequence-non-specific double-stranded DNA binding domains for the invention. For example, a consensus PCNA-interacting sequence can be joined to a polymerase that does not naturally interact with a PCNA homolog, thereby allowing a PCNA homolog to serve as a processivity factor for the polymerase. By way of illustration, the PCNA-interacting sequence from Pyrococcus furiosus PolII (a heterodimeric DNA polymerase containing two family B-like polypeptides) can be covalently joined to Pyrococcus furiosus Poll (a monomeric family B polymerase that does not normally interact with a PCNA homolog). The resulting fusion protein can then be allowed to associate non-covalently with the Pyrococcus furiosus PCNA homolog to generate a novel heterologous protein with increased processivity relative to the unmodified Pyrococcus furiosus Poll.

Other Sequence-Nonspecific Double-Stranded Nucleic Acid Binding Domains

Additional nucleic acid binding domains suitable for use in the invention can be identified by homology with known sequence non-specific double-stranded DNA binding proteins and/or by antibody crossreactivity, or may be found by means of a biochemical assay. These methods are described, e.g., in WO01/92501. Typically, domains that have about 50% amino acid sequence identity, optionally about 60%, 75, 80, 85, 90, or 95-98% amino acid sequence identity to a known sequence non-specific double-stranded nucleic acid binding protein over a comparison window of about 25 amino acids, optionally about 50-100 amino acids, or the length of the entire protein, can be used in the invention. Further, methods of joining the polymerase to the sequence non-specific double-stranded DNA binding protein and methods of expressing recombinant polymerases and polymerase fusion proteins are also described (see, e.g., WO01/92501).

Assays to Determine Improved Activity of Polymerase Domains.

Activity of the polymerase domain can be measured using a variety of assays that can be used to compare processivity or modification activity of a modifying protein domain joined to a binding domain compared to the protein by itself. Improvement in activity includes both increased processivity and increased efficiency.

Polymerase processivity can be measured in variety of methods known to those of ordinary skill in the art. Polymerase processivity is generally defined as the number of nucleotides incorporated during a single binding event of a modifying enzyme to a primed template.

For example, a 5′ FAM-labeled primer is annealed to circular or linearized ssM13 mp18 DNA to form a primed template. In measuring processivity, the primed template usually is present in significant molar excess to the enzyme or catalytic domain to be assayed so that the chance of any primed template being extended more than once by the polymerase is minimized. The primed template is therefore mixed with the polymerase catalytic domain to be assayed at a ratio such as approximately 4000:1 (primed DNA:DNA polymerase) in the presence of buffer and dNTPs. MgCl₂ is added to initiate DNA synthesis. Samples are quenched at various times after initiation, and analyzed on a sequencing gel. At a polymerase concentration where the median product length does not change with time or polymerase concentration, the length corresponds to the processivity of the enzyme. The processivity of a protein of the invention, i.e., a protein that contains a sequence non-specific double-stranded nucleic acid binding domain fused to the catalytic domain of a processive nucleic acid modifying enzyme such as a polymerase, is then compared to the processivity of the enzyme without the binding domain.

Enhanced efficiency can also be demonstrated by measuring the increased ability of an enzyme to produce product. Such an analysis measures the stability of the double-stranded nucleic acid duplex indirectly by determining the amount of product obtained in a reaction. For example, a PCR assay can be used to measure the amount of PCR product obtained with a short, e.g., 12 nucleotide in length, primer annealed at an elevated temperature, e.g., 50° C. In this analysis, enhanced efficiency is shown by the ability of a polymerase such as a Taq polymerase to produce more product in a PCR reaction using the 12 nucleotide primer annealed at 50° C. when it is joined to a sequence-non-specific double-stranded nucleic-acid-binding domain of the invention, e.g., Sso7d, than Taq polymerase does alone. In contrast, a binding tract that is a series of charged residues, e.g. lysines, does not enhance processivity when joined to a polymerase.

Assays such as salt sensitivity can also be used to demonstrate improvement in efficiency of a processive nucleic acid modifying enzyme of the invention. A modifying enzyme, or the catalytic domain, when fused to a sequence non-specific double-stranded nucleic acid binding domain of the invention exhibits increased tolerance to high salt concentrations, i.e., a processive enzyme with increased processivity can produce more product in higher salt concentrations. For example, a PCR analysis can be performed to determine the amount of product obtained in a reaction using a fusion Taq polymerase (e.g., Sso7d fused to Taq polymerase) compared to Taq polymerase in reaction conditions with high salt, e.g., 80 mM.

Other methods of assessing enhanced efficiency of the improved polymerases of the invention can be determined by those of ordinary skill in the art using standard assays of the enzymatic activity of a given modification enzyme.

Uses of Improved Polymerases

The invention provides improved methods of performing polymerase reactions. In one embodiment, the invention provides a method of performing a polymerase reaction in the presence of a fluorescent dye. A number of fluorescent dyes that are commonly used in reactions such as real-time PCR, have an inhibitory activity on polymerases have been typically used in PCR, e.g., Taq polymerase. For example, SYBR Green I (Molecular Probes, Eugene, Oreg.; U.S. Pat. Nos. 5,436,134 and 5,658,751), is a fluorescent dye that is specific for dsDNA detection, and is widely used in real-time PCR reactions to monitor the generation of dsDNA through each cycle of amplification. Use of dyes to monitor amplification is described in U.S. Pat. Nos. 5,994,056 and 6,171,785 and use of SYBR Green I for this purpose is described in Morrison et al., Biotechniques 24:954-962 (1998).

It has been observed that the addition of SYBR Green I inhibits the activity of DNA polymerases used in PCR, possibly through interfering with the binding of the polymerase to the primer-template. Additives such as DMSO are therefore often required to reduce the inhibitory effect of the dye. However, DMSO can reduce the storage stability of the enzyme and can inhibit polymerases. The current invention provides a method of performing polymerase reactions in the presence of a fluorescent dye that uses the improved polymerases described herein, which are not as sensitive to the fluorescent dye, i.e., are not inhibited to the same extent, as an unimproved polymerase.

The ability of a polymerase to perform in the presence of a dye that exhibits altered fluorescence emissions when bound to double-stranded DNA can be measured using well known polymerase assays, such as those described herein. Typically, a fluorescent dye reduces the activity of an unimproved polymerase by 25%, often 50%, 75%, or more. Polymerase activity can be assayed using the methods described herein.

The ability of an improved polymerase to perform a PCR reaction in the presence of a fluorescent dye, e.g., SYBR Green I, can also be compared to the ability of the unimproved polymerase to perform in an otherwise identical PCR reaction. The comparison can be made using a values such as the cycle threshold (C_(t)) value, which represents the number of cycles required to generate a detectable amount of DNA. An efficient polymerase may be able to produce a detectable amount of DNA in a smaller number of cycles by more closely approaching the theoretical maximum amplification efficiency of PCR. Accordingly, a lower C_(t) value reflects a greater amplification efficiency for the enzyme. The improved enzymes exhibit 2×, often 5×, or greater activity in the presence of a fluorescent dye when compared to the unimproved enzyme.

In typical embodiments, the polymerase reaction is performed in the presence of a fluorescent dye such as SYBR Green I or Pico Green I (Molecular Probes, Eugene, Oreg.;). These dyes are unsymmetrical cyanine dyes containing a defined substituent on the pyridinium or quinolinium ring system or a substituent immediately adjacent to the nitrogen atom of the pyridinium or quinolinium ring. These and other members of the same class of dyes are described, e.g., in U.S. Pat. Nos. 5,436,134 and 5,658,751. SYBR Green I, for example, binds specifically to dsDNA with a dissociation constant in the sub-micromolar range. Upon binding, it has a large increase in its quantum yield and therefore a large increase in fluorescence.

In other embodiments, the polymerase reactions of the invention can be performed in the presence of other fluorescent compounds that typically inhibit polymerases, such as other fluorescent dyes, e.g., propidium iodide, ethidium bromide, acridines, proflavine, acridine orange, acriflavine, fluorcoumanin, ellipticine, daunomycin, chloroquine, distamycin D, chromomycin, mithramycin, ruthenium polypyridyls, and anthramycin, which also exhibit altered fluorescence emissions when bound to double-stranded DNA. Improved polymerases can be tested for resistance to other dyes using methodology well known in the arts and described herein (see, e.g., Example 6).

In another embodiment, the invention provides method of performing a polymerase reaction, e.g., a PCR reaction, in the presence of contaminants such as those present when using a crude nucleic acid sample. Inhibitors of polymerase activity are often present in crude nucleic acid sample preparations, thus presenting difficulties in using such preparations in polymerase reactions such as PCR or nucleic acid sequence. The improved enzymes are more tolerant to such contaminants. Accordingly, the improved enzymes offer advantages over standard enzymes when performing polymerase reactions, e.g. PCR, using crude nucleic acid preparations. These preparations can be from a variety of sources, including cells such as bacterial cells, plant cells, and various other cell types.

A crude nucleic acid sample typically includes contaminants that originate from the nucleic acid source or from a previous chemical or molecular biological manipulation. The improved polymerases are less sensitive to the presence of such contaminants. As noted above, polymerase activity assays can be performed using methods described herein. An improved polymerase typically exhibits 2×, 5×, 10×, or greater activity relative to the unimproved polymerase when assayed in the presence of contaminants in an otherwise identical polymerase activity assay or PCR. An exemplary analysis of polymerase activity in crude preparations is provided in Example 7. Crude preparations typically are not processed through repeated rounds of purification and are typically less than 98% pure, often less than 95% pure.

The modified polymerase enzymes are also more resistant to common additives for troublesome PCR reactions such as Betaine, DMSO, as well as resistant to salt, e.g., KCl, etc. The improved polymerase typically exhibits 2×, 5×, 10× or greater activity relative to the unimproved polymerase in the presence of such agents.

Improved polymerases can also be used in nucleic acid sequencing reactions. These reactions are well known to those of skill in the art (see, e.g., Sambrook and Russell, Molecular Cloning, A Laboratory Manual 3rd. 2001, Cold Spring Harbor Laboratory Press).

Improved polymerases are particular advantageous when used in sequencing reactions, in particular sequencing reactions that use thermostable polymerases, such as cycle sequencing reactions. Cycle sequencing refers to a linear amplification DNA sequencing technique in which a single primer is used to generate labeled terminated fragments by the Sanger dideoxy chain termination method. Thermostable polymerase enzymes are employed in such reactions.

Thermostable polymerases such as Taq or Pfu catalyze the incorporation of ddNTPs at a rate that is at least two orders of magnitude slower than the rate of incorporation of dNTPs. In addition, the efficiency of incorporation of a ddNTP at a particular site is affected by the local sequence of the template DNA. Modified version of polymerases that lack 5′ to 3′ exonuclease activity and catalyze incorporation of ddNTPs with high efficiency have been developed; however, their processivity is often poor. For example, thermostable enzymes are such as ΔTaq derivatives, which have Taq polymerase's 5′-3′ nuclease domain removed, have a processivity of about 2 bases. Also, in the case of dye terminator-sequencing, dITP is used in place of dGTP, which causes polymerase pausing and dissociation at G nucleotides. These enzymes therefore produce a large number of sequence products that are improperly terminated. Furthermore, if a polymerase dissociates during primer extension of a template containing a repeat unit (e.g., a triplet repeat) or secondary structure (e.g., a stem and loop) such that the strand is not completed during a particular PCR cycle, the 3′ end can denature and reanneal during a subsequent PCR cycle so as to prime at a different location on the template—for example, in the case of a repeat, the reannealing could occur at a different repeat; or in the case of secondary structure, improper reannealing could delete out a section of the template. Thus, dissociation of the polymerase is also a problem.

The use of improved polymerases as described herein can provide enhanced sequencing reactions, e.g., cycle sequencing reactions, in which there are fewer improper terminations and fewer dissociation events. This provides longer sequence reads, i.e., the number of nucleotides for which the sequence can be determined, that contain fewer ambiguities compared to reaction performed with unimproved enzymes.

The polymerases are typically modified to substitute a Y residue for an F residue (U.S. Pat. No. 5,614,365).

All publications, patents, and patent applications cited in this specification are herein incorporated by reference as if each individual publication or patent application were specifically and individually indicated to be incorporated by reference.

Although the foregoing invention has been described in some detail by way of illustration and example for purposes of clarity of understanding, it will be readily apparent to those of ordinary skill in the art in light of the teachings of this invention that certain changes and modifications may be made thereto without departing from the spirit or scope of the appended claims.

EXAMPLES

The following examples are provided by way of illustration only and not by way of limitation. Those of skill will readily recognize a variety of non-critical parameters that could be changed or modified to yield essentially similar results.

Example 1 Construction of Fusion Proteins

Construction of Sso7d-ΔTaq Fusion.

The following example illustrates the construction of a polymerase protein possessing enhanced processivity, in which the sequence-non-specific double-stranded nucleic acid binding protein Sso7d is fused to the Thermus aquaticus Poll DNA polymerase (a family A polymerase known as Taq DNA polymerase) that is deleted at the N terminus by 289 amino acids (ΔTaq).

Based on the published amino acid sequence of Sso7d, seven oligonucleotides were used in constructing a synthetic gene encoding Sso7d. The oligonucleotides were annealed and ligated using T4 DNA ligase. The final ligated product was used as the template in a PCR reaction using two terminal oligonucleotides as primers to amplify the full-length gene. By design, the resulting PCR fragment contains a unique EcoRI site at the 5′ terminus, and a unique BstXI site at the 3′ terminus. In addition to encoding the Sso7d protein, the above PCR fragment also encodes a peptide linker with the amino acid sequence of Gly-Gly-Val-Thr (SEQ ID NO:34) positioned at the C terminus of the Sso7d protein. The synthetic gene of Sso7d has the DNA sequence shown in SEQ ID NO:1, and it encodes a polypeptide with the amino acid sequence shown in SEQ ID NO:2.

The synthetic gene encoding Sso7d was then used to generate a fusion protein in which Sso7d replaces the first 289 amino acid of Taq. The fragment encoding Sso7d was Subcloned into a plasmid encoding Taq polymerase to generate the fusion protein, as follows. Briefly, the DNA fragment containing the synthetic Sso7d gene was digested with restriction endonucleases EcoRI and BstXI, and ligated into the corresponding sites of a plasmid encoding Taq. As the result, the region that encodes the first 289 amino acid of Taq is replaced by the synthetic gene of Sso7d. This plasmid (pYW1) allows the expression of a single polypeptide containing Sso7d fused to the N terminus of ΔTaq via a synthetic linker composed of Gly-Gly-Val-Thr (SEQ ID NO:34). The DNA sequence encoding the fusion protein (Sso7d-ΔTaq) and the amino acid sequence of the protein are shown in SEQ ID NOs:3 and 4, respectively.

Construction of Sso7d-Taq Fusion.

An Sso7d/full-length Taq fusion protein was also constructed. Briefly, a 1 kb PCR fragment encoding the first 336 amino acids of Taq polymerase was generated using two primers. The 5′ primer introduces a SpeI site into the 5′ terminus of the PCR fragment, and the 3′ primer hybridizes to nucleotides 1008-1026 of the Taq gene. The fragment was digested with SpeI and BstXI, releasing a 0.9 kb fragment encoding the first 289 amino acids of Taq polymerase. The 0.9 kb fragment was ligated into plasmid pYW1 at the SpeI (located in the region encoding the linker) and BstXI sites. The resulting plasmid (pYW2) allows the expression of a single polypeptide containing the Sso7d protein fused to the N terminus of the full length Taq DNA polymerase via a linker composed of Gly-Gly-Val-Thr (SEQ ID NO:34), the same as in Sso7d-ΔTaq. The DNA sequence encoding the Sso7d-Taq fusion protein and the amino acid sequence of the protein are shown in SEQ ID NOS:5 and 6, respectively.

Construction of Pfu-Sso7d Fusion.

A third fusion protein was created, joining Sso7d to the C terminus of Pyrococcus furiosus DNA polI (a family B DNA polymerase known as Pfu). A pET-based plasmid carrying the Pfu DNA polymerase gene was modified so that a unique KpnI site and a unique SpeI site are introduced at the 3′ end of the Pfu gene before the stop codon. The resulting plasmid (pPFKS) expresses a Pfu polymerase with three additional amino acids (Gly-Thr-His) at its C terminus.

Two primers were used to PCR amplify the synthetic Sso7d gene described above to introduce a KpnI site and a NheI site flanking the Sso7d gene. The 5′ primer also introduced six additional amino acids (Gly-Thr-Gly-Gly-Gly-Gly; SEQ ID NO:35), which serve as a linker, at the N terminus of the Sso7d protein. Upon digestion with KpnI and NheI, the PCR fragment was ligated into pPFKS at the corresponding sites. The resulting plasmid (pPFS) allows the expression of a single polypeptide containing Sso7d protein fused to the C terminus of the Pfu polymerase via a peptide linker (Gly-Thr-Gly-Gly-Gly-Gly; SEQ ID NO:35). The DNA sequence encoding the fusion protein (Pfu-Sso7d) and the amino acid sequence of the fusion protein are shown in SEQ ID NOS: 7 and 8, respectively.

Construction of Sac7d-ΔTaq Fusion.

A fourth fusion protein was constructed, which joined a sequence-non-specific DNA binding protein from a different species to ΔTaq. Two primers were used to PCR amplify the Sac7d gene from genomic DNA of Sulfolobus acidocaldarius. The primers introduced a unique EcoRI site and a unique SpeI site to the PCR fragment at the 5′ and 3′ termini, respectively. Upon restriction digestion with EcoRI and SpeI, the PCR fragment was ligated into pYW1 (described above) at the corresponding sites. The resulting plasmid expresses a single polypeptide containing the Sac7d protein fused to the N terminus of ΔTaq via the same linker as used in Sso7d-ΔTaq. The DNA sequence of the fusion protein (Sac7d-ΔTaq) and the amino acid sequence of the protein are shown in SEQ ID. NOs: 9 and 10, respectively.

Construction of PL-ΔTaq Fusion.

A fifth fusion protein joins a peptide composed of 14 lysines and 2 arginines to the N terminus of ΔTaq. To generate the polylysine (PL)-ΔTaq fusion protein, two 67 nt oligonucleotides were annealed to form a duplexed DNA fragment with a 5′ protruding end compatible with an EcoRI site, and a 3′ protruding end compatible with an SpeI site. The DNA fragment encodes a lysine-rich peptide of the following composition: NSKKKKKKKRKKRKKKGGGVT (SEQ ID NO:36). The numbers of lysines and arginines in this peptide are identical to those in Sso7d. This DNA fragment was ligated into pYW1, predigested with EcoRI and SpeI, to replace the region encoding Sso7d. The resulting plasmid (pLST) expresses a single polypeptide containing the lysine-rich peptide fused to the N terminus of ΔTaq. The DNA sequence encoding the fusion protein (PL-ΔTaq) and the amino acid sequence of the protein are shown in SEQ ID NOS: 11 and NO. 12, respectively.

Example 2 Assessing the Processivity of the Fusion Polymerases

This example illustrates enhancement of processivity of the fusion proteins of the invention generated in Example 1.

Polymerase Unit Definition Assay

The following assay was used to define a polymerase unit. An oligonucleotide was pre-annealed to ssM13mp18 DNA in the presence of Mg⁺⁺-free reaction buffer and dNTPs. The DNA polymerase of interest was added to the primed DNA mixture. MgCl₂ was added to initiate DNA synthesis at 72° C. Samples were taken at various time points and added to TE buffer containing PicoGreen (Molecular Probes, Eugene Oreg.). The amount of DNA synthesized was quantified using a fluorescence plate reader. The unit activity of the DNA polymerase of interest was determined by comparing its initial rate with that of a control DNA polymerase (e.g., a commercial polymerase of known unit concentration).

Processivity Assay

Processivity was measured by determining the number of nucleotides incorporated during a single binding event of the polymerase to a primed template.

Briefly, 40 nM of a 5′ FAM-labeled primer (34 nt long) was annealed to 80 nM of circular or linearized ssM13mp18 DNA to form the primed template. The primed template was mixed with the DNA polymerase of interest at a molar ratio of approximately 4000:1 (primed DNA:DNA polymerase) in the presence of standard PCR buffer (free of Mg⁺⁺) and 200 μM of each dNTPs. MgCl₂ was added to a final concentration of 2 mM to initiate DNA synthesis. At various times after initiation, samples were quenched with sequencing loading dye containing 99% formamide, and analyzed on a sequencing gel. The median product length, which is defined as the product length above or below which there are equal amounts of products, was determined based on integration of all detectable product peaks. At a polymerase concentration for which the median product length change with time or polymerase concentration, the length corresponds to the processivity of the enzyme. The ranges presented in Table 1 represent the range of values obtained in several repeats of the assay.

TABLE 1 Comparison of processivity DNA polymerase Median product length (nt) ΔTaq 2-6 Sso7d-ΔTaq 39-58 PL-ΔTaq 2-6 Taq 15-20 Sso7d-Taq 130-160 Pfu 2-3 Pfu-Sso7d 35-39

In comparing the processivity of modified enzyme to the unmodified enzyme, ΔTaq had a processivity of 2-6 nucleotides, whereas Sso7d-ΔTaq fusion exhibited a processivity of 39-58 nucleotides (Table I). Full length Taq had a processivity of 15-20 nucleotides, which was significantly lower than that of Sso7d-Taq fusion with a processivity of 130-160 nucleotides. These results demonstrate that Sso7d joined to Taq polymerase enhanced the processivity of the polymerase.

Pfu belongs to family B of polymerases. Unlike Taq polymerase, Pfu possesses a 3′ to 5′ exonuclease activity, allowing it to maintain high fidelity during DNA synthesis. A modified Pfu polymerase, in which Sso7d is fused to the C terminus of the full length Pfu polymerase and an unmodified Pfu polymerase were analyzed in the processivity assay described above. As shown in Table I, the Pfu polymerase exhibited a processivity of 2-3 nt, whereas the Pfu-Sso7d fusion protein had a processivity of 35-39 nt. Thus, the fusion of Sso7d to the C terminus of Pfu resulted in a >10-fold enhancement of the processivity over the unmodified enzyme.

Example 3 Effect of Fusion Proteins on Oligonucleotide Annealing Temperature

This experiment demonstrates the increased efficiency of the Sso7d-ΔTaq fusion protein, compared to Taq, to produce product at higher annealing temperatures by stabilizing dsDNA.

Two primers, primer 1008 (19mer; T_(M)=56.4° C.) and 2180R (20mer; T_(M)=56.9° C.), were used to amplify a 1 kb fragment (1008-2180) of the Taq pol gene. A gradient thermal cycler (MJ Research, Waltham Mass.) was used to vary the annealing temperature from 50° C. to 72° C. in a PCR cycling program. The amounts of PCR products generated using identical number of units of Sso7d-ΔTaq and Taq were quantified and compared. The results are shown in Table 2. The Sso7d-ΔTaq fusion protein exhibited significantly higher efficiency than full length Taq at higher annealing temperatures. Thus, the presence of Sso7d in cis increases the melting temperature of the primer on the template.

The annealing temperature assay above was used to investigate whether PL-ΔTaq has any effect on the annealing temperature of primer during PCR amplification. As shown in Table 2 little or no amplified product was observed when the annealing temperature was at or above 63° C.

TABLE 2 Comparison of activities at different annealing temperatures. Activity Activity Activity Polymerase at 63° C. at 66° C. at 69° C. Taq   85% 30% <10% Sso7d-ΔTaq >95% 70%   40% PL-ΔTaq  <5% nd nd nd: not detectable.

Example 4 Effect of Fusion Proteins on Required Primer Length

An enhancement of T_(M) of the primers (as shown above) predicts that shorter primers could be used by Sso7d-ΔTaq, but not by Taq, to achieve efficient PCR amplification. This analysis shows that Sso7d-ΔTaq is more efficient in an assay using shorter primers compared to Taq.

Primers of different lengths were used to compare the efficiencies of PCR amplification by Sso7d-ΔTaq and by Taq. The results are shown in Table 3. When two long primers, 57F (22mer, T_(M)=58° C.) and 732R (24mer, T_(M)=57° C.) were used, no significant difference was observed between Sso7d-ΔTaq and Taq at either low or high annealing temperatures. When medium length primers, 57F15 (15mer, T_(M)=35° C.) and 732R16 (16mer, T_(m)=35° C.), were used, Sso7d-ΔTaq was more efficient than Taq, especially when the annealing temperature was high. The most striking difference between the two enzymes was observed with short primers, 57F12 (12mer) and 732R16 (16mer), where Sso7d-ΔTaq generated 10 times more products than Taq at both low and high annealing temperatures.

PCR using primers 57F12 (12 nt) and 732R16 (16 nt) were used to compare the efficiency of Sac7d-ΔTaq to the unmodified full length Taq in PCR reaction. Similar to Sso7d-ΔTaq, Sac7d-ΔTaq is significantly more efficient than Taq in amplifying using short primers.

A primer length assay was used to determine the ability of PL-ΔTaq to use short primers in PCR amplification. When long primers (57F and 732R) were used, the amplified product generated by PL-ΔTaq is ˜50% of that by Sso7d-ΔTaq. When short primers (57F12 and 732R16) were used, the amplified product generated by PL-ΔTaq is <20% of that by Sso7d-ΔTaq.

TABLE 3 Comparison of the effect of primer length on PCR amplification by Sso7d-ΔTaq and Taq DNA polymerase. 22 nt primer 15 nt primer 12 nt primer Anneal @ Anneal @ Anneal @ Anneal @ Anneal @ Anneal @ polymerase 55° C. 63° C. 49° C. 54° C. 49° C. 54° C. Taq 14000  9000  5500  <500  1000 undetectable Sso7d-ΔTaq 17000 13000 15000   5000 10000 3000 Sso7d-ΔTaq:Taq 1.2:1 1.4:1 2.7:1 >10:1 10:1 >10:1 Increased Performance of Fusion Polymerases in PCR Reactions

The increased stability and/or processivity of the fusion proteins of the invention provide increased efficiency in performing various modification reactions. For example, polymerase fusion proteins can provide more efficient amplification in PCR reactions. Many factors influence the outcome of a PCR reaction, including primer specificity, efficiency of the polymerase, quality, quantity and GC-content of the template, length of the amplicon, etc. Examples 5-8 demonstrate that fusion proteins that include a double-stranded sequence-non-specific nucleic acid binding domain, e.g., Sso7d, joined to a thermostable polymerase or polymerase domain have several advantageous features over the unmodified enzyme in PCR applications.

Example 5 Sso7d Fusion Proteins Exhibit a Higher and Broader Salt-Tolerance in PCR

The binding of polymerase to a primed DNA template is sensitive to the ionic strength of the reaction buffer due to electrostatic interactions, which is stronger in low salt concentration and weaker in high. The presence of Sso7d in a fusion polymerase protein stabilizes the binding interaction of the polymerase to DNA template. This example demonstrates that Sso7d fusion proteins exhibit improved performance in PCR reactions containing elevated KCl concentrations.

Lambda DNA (2 pM) was used as a template in a PCR reactions with primers 57F and 732R. The concentration of KCl was varied from 10 mM to 150 mM, while all other components of the reaction buffer were unchanged. The PCR reaction was carried out using a cycling program of 94° C. for 3 min, 20 cycles of 94° C. for 30 sec, 55° C. for 30 sec, and 72° C. for 30 sec, followed by 72° C. for 10 min. Upon completion of the reaction, 5 μl of the PCR reaction was removed and mixed with 195 μl of 1:400 dilution of PicoGreen in TE to quantify the amounts of amplicon generated. The PCR reaction products were also analyzed in parallel on an agarose gel to verify that amplicons of expected length were generated (data not shown). The effects of KCl concentration on the PCR efficiency of Sso7d-ΔTaq versus that of ΔTaq, and Pfu-Sso7d versus Pfu are shown in Table 4. The unmodified enzymes, ΔTaq and Pfu, showed a preference for KCl concentration below 25 mM and 40 mM, respectively, to maintain 80% of the maximum activity. In contrast, fusion proteins Sso7d-ΔTaq and Pfu-Sso7d maintain 80% of the maximum activity in 30-100 mM and 60-100 mM KCl, respectively. Thus, the Sso7d fusion proteins were more tolerant of elevated KCl concentration in comparison to their unmodified counter parts. This feature of the hybrid polymerase will potentially allow PCR amplification from low quality of DNA template, e.g., DNA samples prepared from, but not limited to, blood, food, and plant sources.

TABLE 4 Sso7d modification increases salt-tolerance of polymerase in PCR reaction Enzyme Enzyme concentration [KCl] for 80% activity ΔTaq 20 U/ml <25 mM Sso7d-ΔTaq 20 U/ml 30-100 mM Pfu  3 U/ml <40 mM Pfu-Sso7d 12 U/ml* (equal molar) 60-100 mM *Pfu-Sso7d has a 4-fold higher specific activity than Pfu. The specific activity is defined as unit/mol of enzyme.

Example 6 Sso7d-Fusion Polymerases are more Tolerant to SYBR Green I in Real-Time PCR

Three pairs of unmodified and modified enzymes were compared: commercial ΔTaq (ABI, Foster City, Calif.) vs. Sso7d-ΔTaq, Taq vs. Sso7d-Taq, and commercial Pfu (Stratagene, La Jolla Calif.) vs. Pfu-Sso7d. In addition to the 20U/ml concentration used for all enzymes, a 5-fold higher concentration (100 U/ml) of ΔTaq and Pfu were used as well. The Ct values represent the number of cycles required to generate a detectable amount of DNA, and thus a lower Ct value reflects a greater amplification efficiency for the enzyme. Consistent Ct values are also preferable, indicating the reaction is robust to differences in dye concentration. Two extension times (10s and 30s) were used. The SYBR Green 1 concentration is indicated as 0.5×, etc. The 1×SYBR Green I is defined as a SYBR Green I solution in TE (10 mM Tris pH 7.5, 1 mM EDTA) that has an absorbance at 495 nm of 0.40±0.02. SYBR Green I was purchased from Molecular Probes (Eugene, Oreg.) as a 10,000× stock in DMSO. In all three pairs, the modified polymerase showed significantly higher tolerance of dye. The differences are most striking in the case of ΔTaq vs. Sso7d-ΔTaq.

TABLE 5 Sso7d fusion proteins are more tolerant of SYBR Green I. (The symbol “—” indicates that no amplification was observed in 40 cycles 2 mM 3 mM MgCl2 SYBR Green I SYBR Green I ENZYMES Unit/ml 0.5× 1× 1.5× 2× 2.5× 0.5× 1× 1.5× 2× 2.5× 10 s @ 72° C. ΔTaq 20 — — — — — — — — — — ΔTaq 100 — — — — — — — — — — Sso7d-ΔTaq 20 23.3 22.5 22.5 22.3 22.4 22.9 22.2 22   22.2 21.8 Taq 20 23   23.6 — — — 22.5 22.3 22.6 — — Sso7d-Taq 20 23.3 23.3 23.2 23.5 — 24   24   23.1 23.4 23.6 Pfu 20 31.2 — — — — 31.5 — — — — Pfu 100 21.8 25   — — — 22.6 23.3 30   — — Pfu-Sso7d 20 21.5 22.3 35   — — 21.8 22   22.6 27.2 — 30 s @ 72° C. ΔTaq 20 — — — — — — — — — — ΔTaq 100 — — — — — 26.8 — — — — Sso7d-ΔTaq 20 23.8 22.3 22.6 21.8 21.7 22.3 21   21.3 21.8 21.8 Taq 20 24.2 24.6 29.4 ∞ — 22.8 22.1 22.6 25   — Sso7d-Taq 20 24.2 23.5 23   22.7 24.2 24.7 23.1 23.6 23.1 22.9 Pfu 20 33.2 — — — — 29.4 — — — — Pfu 100 27.6 30.6 — — — 24.8 29.8 — — — Pfu-Sso7d 20 25   24.8 25.4 24.4 — 23.1 25.3 23.6 26.1 —

Example 7 Sso7d-Fusion Polymerases are more Tolerant to Crude Template Preparations

A. Resistance to Bacterial Contamination in PCR

Colony PCR is a useful technique in which small samples of single bacterial colonies are lysed and added directly to PCR reactions for the purpose of screening the colonies for particular DNA sequences. Colony PCR has a high failure rate, presumably because of contaminants carries over from the colony. Polymerases resistant to cell extracts are desirable because they presumably will be more successful in colony PCR.

Materials For “Dirty” PCR

-   Lambda template (10 ng/ml): amplicon is a 891 bp fragment -   Primers 56F/55R (T_(M) 56° and 55°), 400 nM -   Enzymes: Sst (Sso7d-ΔTaq) vs. PE Stf (ΔTaq), STq (Sso7d-Taq) vs.     Taq-HIS or AmpliTaq or Amersham Taq, and Stratagene Pfu vs. PfS     (Pfu-Sso7d) All enzymes are 20 U/ml except where indicated -   200 μM each dNTP -   2 mM MgCl₂, except 1.5 mM for Amersham Taq and AmpliTaq -   Reactions were 20 μl     Methods:

E. coli were grown to saturation, spun down, suspended in water at an OD of 100, and frozen and thawed to disrupt cells. Dilutions of the disrupted bacteria were added at various concentrations to PCR reactions containing lambda DNA as template and two primers to amplify a 890 bp amplicon. IX is equivalent to an OD of 10 (10 OD units/ml). The cycling conditions were as follows:

-   1) 95° C.—20″ -   2) 94° C.—5″ -   3) 60° C.—15″ -   4) 72° C.—45″ -   5) repeat steps 2-4 19 times -   6) 72° C.—5′ -   7) 4° C. forever -   8) END

The experiment showed that Sso7d-ΔTaq significantly out performed Stoffel fragment (Applied Biosystems, Foster City, Calif.). Stoffel (Stf) is a trade name for a preparation of ΔTaq. Using 20 U/ml enzyme in the final reaction, Sso7d-ΔTaq allowed PCR amplification in the presence of 0.25× of cell dilution. When the same unit concentrations of Stoffel was used, no detectable product was generated, even in the most dilute cell solution. When 220 u/ml Stoffel was used, a detectable amount of product was generated at a 0.06× or lower concentration of the cell dilution. Thus, the resistance of Sso7d-ΔTaq to bacterial contamination in PCR reaction is more than 10-folder higher than that of the unmodified enzyme Stoffel.

Similarly, Pfu-Sso7d showed more resistance to bacterial contamination than Pfu, although both enzymes appeared to be more sensitive to the contamination than Taq-based enzymes. With 20 U/ml enzyme in the final reaction, Pfu allowed amplification only in the presence of 0.00006× or lower concentrations of cell dilution. In contrast, Pfu-Sso7d allowed efficient PCR amplification in 0.002× of cell dilution. Thus, Pfu-Sso7d has a 30-fold higher tolerance to bacterial contamination in PCR than the unmodified enzyme Pfu.

B. Resistance to Plant and Blood Contamination in PCR

The same problems exist with other crude template preparations. PCR fails due to contaminants carried over in the template preparation. This example shows results with crude plant and blood preps. Dilution series were made of plant leaf homogenate from Fritallaria agrestis, a species of lily, and whole human blood. Dilutions were made with 1×TE, pH 8.0 at 1/10, 1/100, 1/1000. One microliter of a dilution was added to the appropriate reaction mix. The PCR cycling protocol was as follows:

-   -   94° C. 2 min     -   94° C. 10 sec     -   59° C. 20 sec for Taq & Sso7d-Taq (54° C. for Pfu & Pfu-Sso7d)     -   72° C. 30 sec     -   repeat cycle 34 times     -   72° C. 10 min

The reaction products were analyzed on agarose gels (FIG. 1A and FIG. 1B). FIG. 1A shows a comparison of the contamination resistance of Pfu vs. PfS. Lanes 1-4 and 14-17 show progressive 10-fold dilutions of plant leaf homogenate. Pfu shows significant inhibition by a 1:10 dilution (lane 2), while PfS is completely resistant to this dilution (lane 7). Similarly, lanes 6-9 and 19-22 show progressive 10-fold dilutions of blood. Pfu is significantly inhibited by 1 microliter of blood, while PfS is resistant. Lanes 10 and 23 are positive controls (no plant or blood), while lanes 11 and 24 are negative controls (no plant or blood or template).

FIG. 1B shows a comparison between Taq and Sso7d-Taq. The upper panel shows reactions performed with 20 U/ml Taq, and the lower panel shows reactions performed with 20 U/ml Sso7d-Taq. Lanes 1-4 in each panel show progressive 10-fold dilutions of plant leaf homogenate and lanes 7-10 show progressive 10-fold dilutions of blood. Sso7d-Taq can amplify a product even in the presence of 1 μl whole blood, while Taq is inhibited by 100-fold less blood. Lanes 5 are positive controls (no plant or blood), while lanes 11 are negative controls (no plant or blood or template).

Example 8 Sso7d-Fusion Polymerases have Advantages in Cycle Sequencing

Plasmid clones encoding improved polymerases suitable for DNA sequencing have been constructed, and the protein products have been purified. The first enzyme is Sso7d-ΔTaq(Y), (SEQ ID No: 30 and 31 with mutations indicated in bold font) which is the same as the enzyme Sso7d-ΔTaq, except modified according to the method of Tabor and Richardson (U.S. Pat. No. 5,614,365) to have a “Y” substituted for an “F” residue at the indicated position in SEQ ID NO:31. The second enzyme is Sso7d-ΔTaq(E5;Y) (SEQ ID No: 32 and 33) with mutations indicated in bold font) which is the same as Sso7d-Taq, except modified according to the method of Tabor and Richardson and also containing point mutations that inactivate the 5′-3′ nuclease domain.

The processivity of each Sso7d fusion polymerase was compared to its unmodified counterpart, i.e., the polymerase without the Sso7d domain. The results in Table 6 show that the Sso7d fusion polymerases are more processive.

TABLE 6 Median Processivity Product Length at 10 mM KCl ΔTaq (Y)  3 to 4 nts. Sso7d-ΔTaq (Y) 11 to 13 nts. ΔTaq (E5)(Y)  5 to 6 nts. Sso7d- 34 to 47 nts. ΔTaq (E5)(Y)

Sequencing reactions using the fusion polymerases and their unmodified counterparts were performed by separating the components of a commercial sequencing kit (BigDye terminator Kit v.3, ABI, Foster City Calif.). Low-molecular-weight components were separated from the enzymes by ultrafiltration. Sequencing reactions performed by combining the low-molecular-weight fraction with the improved enzymes showed good signal strength vs. base number curves. Furthermore, the improved polymerases, e.g., Sso7d-ΔTaq(E5;Y), was able to continued through a hard stop better the other enzymes. Such an improved polymerase is also able to continue through dinucleotide, trinucletide, and long single base repeats more effectively than a counterpart polymerase.

Optimization of the sequencing reactions will demonstrate improvements in peak height evenness, contamination resistance, and lowered requirement for template and/or enzyme concentration.

Table of sequences Synthetic Sso7d gene GCAACCGTAAAGTTCAAGTACAAAGGCGAAGAAAAAGAGGTAGACATCTCCAA SEQ ID NO: 1 GATCAAGAAAGTATGGCGTGTGGGCAAGATGATCTCCTTCACCTACGACGAGGG CGGTGGCAAGACCGGCCGTGGTGCGGTAAGCGAAAAGGACGCGCCGAAGGAGC TGCTGCAGATGCTGGAGAAGCAGAAAAAG The amino acid sequence of Sso7d ATVKFKYKGEEKEVDISKIKKVWRVGKMISFTYDEGGGKTGRGAVSEKDAPKELLQ SEQ ID NO: 2 MLEKQKK The DNA sequence encoding the Sso7d-ΔTaq fusion protein ATGATTACGAATTCGAGCGCAACCGTAAAGTTCAAGTACAAAGGCGAAGAAAAA SEQ ID NO: 3 GAGGTAGACATCTCCAAGATCAAGAAAGTATGGCGTGTGGGCAAGATGATCTCC TTCACCTACGACGAGGGCGGTGGCAAGACCGGCCGTGGTGCGGTAAGCGAAAAG GACGCGCCGAAGGAGCTGCTGCAGATGCTGGAGAAGCAGAAAAAGGGCGGCGG TGTCACTAGTCCCAAGGCCCTGGAGGAGGCCCCCTGGCCCCCGCCGGAAGGGGCC TTCGTGGGCTTTGTGCTTTCCCGCAAGGAGCCCATGTGGGCCGATCTTCTGGCCCT GGCCGCCGCCAGGGGGGGCCGGGTCCACCGGGCCCCCGAGCCTTATAAAGCCCT CAGGGACCTGAAGGAGGCGCGGGGGCTTCTCGCCAAAGACCTGAGCGTTCTGGC CCTGAGGGAAGGCCTTGGCCTCCCGCCCGGCGACGACCCCATGCTCCTCGCCTAC CTCCTGGACCCTTCCAACACCACCCCCGAGGGGGTGGCCCGGCGCTACGGCGGG GAGTGGACGGAGGAGGCGGGGGAGCGGGCCGCCCTTTCCGAGAGGCTCTTCGCC AACCTGTGGGGGAGGCTTGAGGGGGAGGAGAGGCTCCTTTGGCTTTACCGGGAG GTGGAGAGGCCCCTTTCCGCTGTCCTGGCCCACATGGAGGCCACGGGGGTGCGC CTGGACGTGGCCTATCTCAGGGCCTTGTCCCTGGAGGTGGCCGAGGAGATCGCCC GCCTCGAGGCCGAGGTCTTCCGCCTGGCCGGCCACCCCTTCAACCTCAACTCCCG GGACCAGCTGGAAAGGGTCCTCTTTGACGAGCTAGGGCTTCCCGCCATCGGCAA GACGGAGAAGACCGGCAAGCGCTCCACCAGCGCCGCCGTCCTGGAGGCCCTCCG CGAGGCCCACCCCATCGTGGAGAAGATCCTGCAGTACCGGGAGCTCACCAAGCT GAAGAGCACCTACATTGACCCCTTGCCGGACCTCATCCACCCCAGGACGGGCCG CCTCCACACCCGCTTCAACCAGACGGCCACGGCCACGGGCAGGCTAAGTAGCTC CGATCCCAACCTCCAGAACATCCCCGTCCGCACCCCGCTTGGGCAGAGGATCCGC CGGGCCTTCATCGCCGAGGAGGGGTGGCTATTGGTGGCCCTGGACTATAGCCAG ATAGAGCTCAGGGTGCTGGCCCACCTCTCCGGCGACGAGAACCTGATCCGGGTCT TCCAGGAGGGGCGGGACATCCACACGGAGACCGCCAGCTGGATGTTCGGCGTCC CCCGGGAGGCCGTGGACCCCCTGATGCGCCGGGCGGCCAAGACCATCAACTTCG GGGTCCTCTACGGCATGTCGGCCCACCGCCTCTCCCAGGAGCTAGCCATCCCTTA CGAGGAGGCCCAGGCCTTCATTGAGCGCTACTTTCAGAGCTTCCCCAAGGTGCGG GCCTGGATTGAGAAGACCCTGGAGGAGGGCAGGAGGCGGGGGTACGTGGAGAC CCTCTTCGGCCGCCGCCGCTACGTGCCAGACCTAGAGGCCCGGGTGAAGAGCGT GCGGGAGGCGGCCGAGCGCATGGCCTTCAACATGCCCGTCCAGGGCACCGCCGC CGACCTCATGAAGCTGGCTATGGTGAAGCTCTTCCCCAGGCTGGAGGAAATGGG GGCCAGGATGCTCCTTCAGGTCCACGACGAGCTGGTCCTCGAGGCCCCAAAAGA GAGGGCGGAGGCCGTGGCCCGGCTGGCCAAGGAGGTCATGGAGGGGGTGTATCC CCTGGCCGTGCCCCTGGAGGTGGAGGTGGGGATAGGGGAGGACTGGCTCTCCGC CAAGGAGGGCATTGATGGCCGCGGCGGAGGCGGGCATCATCATCATCATCATTAA The amino acid sequence of Sso7d-ΔTaq fusion protein MITNSSATVKFKYKGEEKEVDISKIKKVWRVGKMISFTYDEGGGKTGRGAVSEKDA SEQ ID NO: 4 PKELLQMLEKQKKGGGVTSPKALEEAPWPPPEGAFVGFVLSRKEPMWADLLALAA ARGGRVHRAPEPYKALRDLKEARGLLAKDLSVLALREGLGLPPGDDPMLLAYLLDP SNTTPEGVARRYGGEWTEEAGERAALSERLFANLWGRLEGEERLLWLYREVERPLS AVLAHMEATGVRLDVAYLRALSLEVAEEIARLEAEVFRLAGHPFNLNSRDQLERVLF DELGLPAIGKTEKTGKRSTSAAVLEALREAHPIVEKILQYRELTKLKSTYIDPLPDLIH PRTGRLHTRFNQTATATGRLSSSDPNLQNIPVRTPLGQRIRRAFIAEEGWLLVALDYS QIELRVLAHLSGDENLIRVFQEGRDIHTETASWMFGVPREAVDPLMRRAAKTTNFGV LYGMSAHRLSQELAIPYEEAQAFIERYFQSFPKVRAWIEKTLEEGRRRGYVETLFGRR RYVPDLEARVKSVREAAERMAFNMPVQGTAADLMKLAMVKLFPRLEEMGARMLL QVHDELVLEAPKERAEAVARLAKEVMEGVYPLAVPLEVEVGIGEDWLSAKEGIDGR GGGGHHHHHH The DNA sequence encoding the Sso7d-Taq fusion protein ATGATTACGAATTCGAGCGCAACCGTAAAGTTCAAGTACAAAGGCGAAGAAAAA SEQ ID NO: 5 GAGGTAGACATCTCCAAGATCAAGAAAGTATGGCGTGTGGGCAAGATGATCTCC TTCACCTACGACGAGGGCGGTGGCAAGACCGGCCGTGGTGCGGTAAGCGAAAAG GACGCGCCGAAGGAGCTGCTGCAGATGCTGGAGAAGCAGAAAAAGGGCGGCGG TGTCACTAGTGGGATGCTGCCCCTCTTTGAGCCCAGGGCCGGGTCCTCCTGGTG GACGGCCACCACCTGGCCTACCGCACCTTCCACGCCCTGAAGGGCCTCACCACCA GCCGGGGGGAGCCGGTGCAGGCGGTCTACGGCTTCGCCAAGAGCCTCCTCAAGG CCCTCAAGGAGGACGGGGACGCGGTGATCGTGGTCTTTGACGCCAAGGCCCCCT CCTTCCGCCACGAGGCCTACGGGGGGTACAAGGCGGGCCGGGCCCCCACGCCAG AGGACTTTCCCCGGCAACTCGCCCTCATCAAGGAGCTGGTGGACCTCCTGGGGCT GGCGCGCCTCGAGGTCCCGGGCTACGAGGCGGACGACGTCCTGGCCAGCCTGGC CAAGAAGGCGGAAAAGGAGGGCTACGAGGTCCGCATCCTCACCGCCGACAAAG ACCTTTACCAGCTCCTTTCCGACCGCATCCACGTCCTCCACCCCGAGGGGTACCT CATCACCCCGGCCTGGCTTTGGGAAAAGTACGGCCTGAGGCCCGACCAGTGGGC CGACTACCGGGCCCTGACCGGGGACGAGTCCGACAACCTTCCCGGGGTCAAGGG CATCGGGGAGAAGACGGCGAGGAAGCTTCTGGAGGAGTGGGGGAGCCTGGAAG CCCTCCTCAAGAACCTGGACCGGCTGAAGCCCGCCATCCGGGAGAAGATCCTGG CCCACATGGACGATCTGAAGCTCTCCTGGGACCTGGCCAAGGTGCGCACCGACCT GCCCCTGGAGGTGGACTTCGCCAAAAGGCGGGAGCCCGACCGGGAGAGGCTTAG GGCCTTTCTGGAGAGGCTTGAGTTTGGCAGCCTCCTCCACGAGTTCGGCCTTCTG GAAAGCCCCAAGGCCCTGGAGGAGGCCCCCTGGCCCCCGCCGGAAGGGGCCTTC GTGGGCTTTGTGCTTTCCCGCAAGGAGCCCATGTGGGCCGATCTTCTGGCCCTGG CCGCCGCCAGGGGGGGCCGGGTCCACCGGGCCCCCGAGCCTTATAAAGCCCTCA GGGACCTGAAGGAGGCGCGGGGGCTTCTCGCCAAAGACCTGAGCGTTCTGGCCC TGAGGGAAGGCCTTGGCCTCCCGCCCGGCGACGACCCCATGCTCCTCGCCTACCT CCTGGACCCTTCCAACACCACCCCCGAGGGGGTGGCCCGGCGCTACGGCGGGGA GTGGACGGAGGAGGCGGGGGAGCGGGCCGCCCTTTCCGAGAGGCTCTTCGCCAA CCTGTGGGGGAGGCTTGAGGGGGAGGAGAGGCTCCTTTGGCTTTACCGGGAGGT GGAGAGGCCCCTTTCCGCTGTCCTGGCCCACATGGAGGCCACGGGGGTGCGCCT GGACGTGGCCTATCTCAGGGCCTTGTCCCTGGAGGTGGCCGAGGAGATCGCCCG CCTCGAGGCCGAGGTCTTCCGCCTGGCCGGCCACCCCTTCAACCTCAACTCCCGG GACCAGCTGGAAAGGGTCCTCTTTGACGAGCTAGGGCTTCCCGCCATCGGCAAG ACGGAGAAGACCGGCAAGCGCTCCACCAGCGCCGCCGTCCTGGAGGCCCTCCGC GAGGCCCACCCCATCGTGGAGAAGATCCTGCAGTACCGGGAGCTCACCAAGCTG AAGAGCACCTACATTGACCCCTTGCCGGACCTCATCCACCCCAGGACGGGCCGCC TCCACACCCGCTTCAACCAGACGGCCACGGCCACGGGCAGGCTAAGTAGCTCCG ATCCCAACCTCCAGAACATCCCCGTCCGCACCCCGCTTGGGCAGAGGATCCGCCG GGCCTTCATCGCCGAGGAGGGGTGGCTATTGGTGGCCCTGGACTATAGCCAGAT AGAGCTCAGGGTGCTGGCCCACCTCTCCGGCGACGAGAACCTGATCCGGGTCTTC CAGGAGGGGCGGGACATCCACACGGAGACCGCCAGCTGGATGTTCGGCGTCCCC CGGGAGGCCGTGGACCCCCTGATGCGCCGGGCGGCCAAGACCATCAACTTCGGG GTCCTCTACGGCATGTCGGCCCACCGCCTCTCCCAGGAGCTAGCCATCCCTTACG AGGAGGCCCAGGCCTTCATTGAGCGCTACTTTCAGAGCTTCCCCAAGGTGCGGGC CTGGATTGAGAAGACCCTGGAGGAGGGCAGGAGGCGGGGGTACGTGGAGACCC TCTTCGGCCGCCGCCGCTACGTGCCAGACCTAGAGGCCCGGGTGAAGAGCGTGC GGGAGGCGGCCGAGCGCATGGCCTTCAACATGCCCGTCCAGGGCACCGCCGCCG ACCTCATGAAGCTGGCTATGGTGAAGCTCTTCCCCAGGCTGGAGGAAATGGGGG CCAGGATGCTCCTTCAGGTCCACGACGAGCTGGTCCTCGAGGCCCCAAAAGAGA GGGCGGAGGCCGTGGCCCGGCTGGCCAAGGAGGTCATGGAGGGGGTGTATCCCC TGGCCGTGCCCCTGGAGGTGGAGGTGGGGATAGGGGAGGACTGGCTCTCCGCCA AGGAGGGCATTGATGGCCGCGGCGGAGGCGGGCATCATCATCATCATCATTAA The amino acid sequence of Sso7d-Taq fusion protein MITNSSATVKFKYKGEEKEVDISKIKKVWRVGKMISFTYDEGGGKTGRGAVSEKDA SEQ ID NO: 6 PKELLQMLEKQKKGGGVTSGMLPLFEPKGRVLLVDGHHLAYRTFHALKGLTTSRGE PVQAVYGFAKSLLKALKEDGDAVIVVFDAKAPSFRHEAYGGYKAGRAPTPEDFPRQ LALIKELVDLLGLARLEVPGYEADDVLASLAKKAEKEGYEVRILTADKLYQLLSDR IHVLHPEGYLITPAWLWEKYGLRPDQWADYRALTGDESDNLPGVKGIGEKTARKLL EEWGSLEALLKNLDRLKPAIREKILAHMDDLKLSWDLAKVRTDLPLEVDFAKRREP DRERLRAFLERLEFGSLLHEFGLLESPKALEEAPWPPPEGAFVGFVLSRKEPMWADL LALAAARGGRVHRAPEPYKALRDLKEARGLLAKDLSVLALREGLGLPPGDDPMLLA YLLDPSNTTPEGVARRYGGEWTEEAGERAALSERLFANLWGRLEGEERLLWLYREV ERPLSAVLAHMEATGVRLDVAYLRALSLEVAEEIARLEAEVFRLAGHPFNLNSRDQL ERVLFDELGLPAIGKTEKTGKRSTSAAVLEALREAHPIVEKILQYRELTKLKSTYIDPL PDLIHPRTGRLHTRFNQTATATGRLSSSDPNLQNIPVRTPLGQRIRRAFIAEEGWLLVA LDYSQIELRVLAHLSGDENLIRVFQEGRDIHTETASWMFGVPREAVDPLMRRAAKTI NFGVLYGMSAHRLSQELAIPYEEAQAFIERYFQSFPKVRAWIEKTLEEGRRRGYVETL FGRRRYVPDLEARVKSVREAAERMAFNMPVQGTAADLMKLAMVKLFPRLEEMGA RMLLQVHDELVLEAPKERAEAVARLAKEVMEGVYPLAVPLEVEVGIGEDWLSAKE GIDGRGGGGHHHHHH The DNA sequence encoding the Pfu-Sso7d fusion protein ATGATTTTAGATGTGGATTACATAACTGAAGAAGGAAAACCTGTTATTAGGCTAT SEQ ID NO: 7 TCAAAAAAGAGAACGGAAAATTTAAGATAGAGCATGATAGAACTTTTAGACCAT ACATTTACGCTCTTCTCAGGGATGATTCAAAGATTGAAGAAGTTAAGAAAATAAC GGGGGAAAGGCATGGAAAGATTGTGAGAATTGTTGATGTAGAGAAGGTTGAGAA AAAGTTTCTCGGCAAGCCTATTACCGTGTGGAAACTTTATTTGGAACATCCCCAA GATGTTCCCACTATTAGAGAAAAAGTTAGAGAACATCCAGCAGTTGTGGACATCT TCGAATACGATATTCCATTTGCAAAGAGATACCTCATCGACAAAGGCCTAATACC AATGGAGGGGGAAGAAGAGCTAAAGATTCTTGCCTTCGATATAGAAACCCTCTA TCACGAAGGAGAAGAGTTTGGAAAAGGCCCAATTATAATGATTAGTTATGCAGA TGAAAATGAAGCAAAGGTGATTACTTGGAAAAACATAGATCTTCCATACGTTGA GGTTGTATCAAGCGAGAGAGAGATGATAAAGAGATTTCTCAGGATTATCAGGGA GAAGGATCCTGACATTATAGTTACTTATAATGGAGACTCATTCGACTTCCCATAT TTAGCGAAAAGGGCAGAAAAACTTGGGATTAAATTAACCATTGGAAGAGATGGA AGCGAGCCCAAGATGCAGAGAATAGGCGATATGACGGCTGTAGAAGTCAAGGG AAGAATACATTTCGACTTGTATCATGTAATAACAAGGACAATAAATCTCCCAACA TACACACTAGAGGCTGTATATGAAGCAATTTTTGGAAAGCCAAAGGAGAAGGTA TACGCCGACGAGATAGCAAAAGCCTGGGAAAGTGGAGAGAACCTTGAGAGAGTT GCCAAATACTCGATGGAAGATGCAAAGGCAACTTATGAACTCGGGAAAGAATTC CTTCCAATGGAAATTCAGCTTTCAAGATTAGTTGGACAACCTTTATGGGATGTTT CAAGGTCAAGCACAGGGAACCTTGTAGAGTGGTTCTTACTTAGGAAAGCCTACG AAAGAAACGAAGTAGCTCCAAACAAGCCAAGTGAAGAGGAGTATCAAAGAAGG CTCAGGGAGAGCTACACAGGTGGATTCGTTAAAGAGCCAGAAAAGGGGTTGTGG GAAAACATAGTATACCTAGATTTTAGAGCCCTATATCCCTCGATTATAATTACCC ACAATGTTTCTCCCGATACTCTAAATCTTGAGGGATGCAAGAACTATGATATCGC TCCTCAAGTAGGCCACAAGTTCTGCAAGGACATCCCTGGTTTTATACCAAGTCTC TTGGGACATTTGTTAGAGGAAAGACAAAAGATTAAGACAAAAATGAAGGAAAACT CAAGATCCTATAGAAAAAATACTCCTTGACTATAGACAAAAAGCGATAAAACTC TTAGCAAATTCTTTCTACGGATATTATGGCTATGCAAAAGCAAGATGGTACTGTA AGGAGTGTGCTGAGAGCGTTACTGCCTGGGGAAGAAAGTACATCGAGTTAGTAT GGAAGGAGCTCGAAGAAAAGTTTGGATTTAAAGTCCTCTACATTGACACTGATG GTCTCTATGCAACTATCCCAGGAGGAGAAAGTGAGGAAATAAAGAAAAGAGGCTC TAGAATTTGTAAAATACATAAATTCAAAGCTCCCTGGACTGCTAGAGCTTGAATA TGAAGGGTTTTATAAGAGGGGATTCTTCGTTACGAAGAAGAGGTATGCAGTAAT AGATGAAGAAGGAAAAGTCATTACTCGTGGTTTAGAGATAGTTAGGAGAGATTG GAGTGAAATTGCAAAGAAACTCAAGCTAGAGTTTTGGAGACAATACTAAAACA CGGAGATGTTGAAGAAGCTGTGAGAATAGTAAAAGAAGTAATACAAAAGCTTGC CAATTATGAAATTCCACCAGAGAAGCTCGCAATATATGAGCAGATAACAAGACC ATTACATGAGTATAAGGCGATAGGTCCTCACGTAGCTGTTGCAAAGAAACTAGCT GCTAAAGGAGTTAAAATAAAGCCAGGAATGGTAATTGGATACATAGTACTTAGA GGCGATGGTCCAATTAGCAATAGGGCAATTCTAGCTGAGGAATACGATCCCAAA AAGCACAAGTATGACGCAGAATATTACATTGAGAACCAGGTTCTTCCAGCGGTA CTTAGGATATTGGAGGGATTTGGATACAGAAAGGAAGACCTCAGATACCAAAAG ACAAGACAAGTCGGCCTAACTTCCTGGCTTAACATTAAAAAATCCGGTACCGGC GGTGGCGGTGCAACCGTAAAGTTCAAGTACAAAGGCGAAGAAAAAGAGGTAGA CATCTCCAAGATCAAGAAAGTATGGCGTGTGGGCAAGATGATCTCCTTCACCTAC GACGAGGGCGGTGGCAAGACCGGCCGTGGTGCGGTAAGCGAAAAGGACGCGCC GAAGGAGCTGCTGCAGATGCTGGAGAAGCAGAAAAAGTGA The amino acid sequence of the Pfu-Sso7d fusion protein MILDVDYITEEGKVIRLFKKENGKFKIEHDRTFRPYIYALLRDDSKIEEVKKITGERH SEQ ID NO: 8 GKIVRIVDVEKVEKKFLGRPITVWKLYLEHPQDVPTIREKVREHPAVVDIFEYDIPFA KRYLIDKGLIPMEGEEELKILAFDIETLYHEGEEFGKGPIIMISYADENEAKVITWKNID LPYVEVVSSEREMIKRFLRIIREKDPDIIVTYNGDSFDFPYLAKRAEKLGIKLTIGRDGS EPKMQRIGDMTAVEVKGRIHFDLYHVITRTINLPTYTLEAVYEAIFGKPKEKVYADEI AKAWESGENLERVAKYSMEDAKATYELGKEFLPMEIQLSRLVGQPLWDVSRSSTGN LVEWFLLRKAYERNEVAPNKPSEEEYQRRLRESYTGGFVKEPEKGLWENIVYLDFR ALYPSIIITHNVSPDTLNLEGCKNYDIAPQVGHKFCKDIPGFIPSLLGHLLEERQKIKTK MKETQDPIEKILLDYRQKAIKLLANSFYGYYGYAKARWYCKECAESVTAWGRKYIE LVWKELEEKFGFKVLYIDTDGLYATIPGGESEEIKKKALEFVKYINSKLPGLLELEYE GFYKRGFFVTKKRYAVIDEEGKVITRGLEIVRRDWSEIAKETQARVLETILKHGDVEE AVRIVKEVIQKLANYEIPPEKLAIYEQITRPLHEYKAIGPHVAVAKKLAAKGVKIKPG MVIGYIVLRGDGPISNRAILAEEYDPKKHKYDAEYYIENQVLPAVLRILEGFGYRKED LRYQKTRQVGLTSWLNIKKSGTGGGGATVKFKYKGEEKEVDISKIKKVWRVGKMIS FTYDEGGGKTGRGAVSEKDAPKELLQMLEKQKK The DNA sequence encoding the Sac7d-ΔTaq fusion protein ATGATTACGAATTCGACGGTGAAGGTAAAGTTCAAGTATAAGGGTGAAGAGAAA SEQ ID NO: 9 GAAGTAGACACTTCAAAGATAAAGAAGGTTTGGAGAGTAGGCAAAATGGTGTCC TTTACCTATGACGACAATGGTAAGACAGGTAGAGGAGCTGTAAGCGAGAAAGAT GCTCCAAAAGAATTATTAGACATGTTAGCAAGAGCAGAAAGAGAGAAGAAAGG CGGCGGTGTCACTAGTCCCAAGGCCCTGGAGGAGGCCCCCTGGCCCCCGCCGGA AGGGGCCTTCGTGGGCTTTGTGCTTTCCCGCAAGGAGCCCATGTGGGCCGATCTT CTGGCCCTGGCCGCCGCCAGGGGGGGCCGGGTCCACCGGGCCCCCGAGCCTTAT AAAGCCCTCAGGGACCTGAAGGAGGCGCGGGGGCTTCTCGCCAAAGACCTGAGC GTTCTGGCCCTGAGGGAAGGCCTTGGCCTCCCGCCCGGCGACGACCCCATGCTCC TCGCCTACCTCCTGGACCCTTCCAACACCACCCCCGAGGGGGTGGCCCGGCGCTA CGGCGGGGAGTGGACGGAGGAGGCGGGGGAGCGGGCCGCCCTTTCCGAGAGGC TCTTCGCCAACCTGTGGGGGAGGCTTGAGGGGGAGGAGAGGCTCCTTTGGCTTTA CCGGGAGGTGGAGAGGCCCCTTTCCGCTGTCCTGGCCCACATGGAGGCCACGGG GGTGCGCCTGGACGTGGCCTATCTCAGGGCCTTGTCCCTGGAGGTGGCCGAGGA GATCGCCCGCCTCGAGGCCGGGTCTTCCGCCTGGCCGGCCACCCCTTCAACCTCA ACTCCCGGGACCAGCTGGAAAGGGTCCTCTTTGACGAGCTAGGGCTTCCCGCCAT CGGCAAGACGGAGAAGACCGGCAAGCGCTCCACCAGCGCCGCCGTCCTGGAGGC CCTCCGCGAGGCCCACCCCATCGTGGAGAAGATCCTGCAGTACCGGGAGCTCAC CAAGCTGAAGAGCACCTACATTGACCCCTTGCCGGACCTCATCCACCCCAGGACG GGCCGCCTCCACACCCGCTTCAACCAGACGGCCACGGCCACGGGCAGGCTAACT AGCTCCGATCCCAACCTCCAGAACATCCCCGTCCGCACCCCGCTTGGGCAGAGGA TCCGCCGGGCCTTCATCGCCGAGGAGGGGTGGCTATTGGTGGCCCTGGACTATAG CCAGATAGAGCTCAGGGTGCTGGCCCACCTCTCCGGCGACGAGAACCTGATCCG GGTCTTCCAGGAGGGGCGGGACATCCACACGGAGACCGCCAGCTGGATGTTCGG CGTCCCCCGGGAGGCCGTGGACCCCCTGATGCGCCGGGCGGCCAAGACCATCAA CTTCGGGGTCCTCTACGGCATGTCGGCCCACCGCCTCTCCCAGGAGCTAGCCATC CCTTACGAGGAGGCCCAGGCCTTCATTGAGCGCTACTTTCAGAGCTTCCCCAAGG TGCGGGCCTGGATTGAGAAGACCCTGGAGGAGGGCAGGAGGCGGGGGTACGTG GAGACCCTCTTCGGCCGCCGCCGCTACGTGCCAGACCTAGAGGCCCGGGTGAAG AGCGTGCGGGAGGCGGCCGAGCGCATGGCCTTCAACATGCCCGTCCAGGGCACC GCCGCCGACCTCATGAAGCTGGCTATGGTGAAGCTCTTCCCCAGGCTGGAGGAA ATGGGGGCCAGGATGCTCCTTCAGGTCCACGACGAGCTGGTCCTCGAGGCCCCA AAAGAGAGGGCGGAGGCCGTGGCCCGGCTGGCCAAGGAGGTCATGGAGGGGGT GTATCCCCTGGCCGTGCCCCTGGAGGTGGAGGTGGGGATAGGGGAGGACTGGCT CTCCGCCAAGGAGGGCATTGATGGCCGCGGCGGAGGCGGGCATCATCATCATCA TCATTAA The amino acid sequence of the Sac7d-ΔTaq fusion protein MITNSTVKVKFKYKGEEKEVDTSKIKKVWRVGKMVSFTYDDNGKTGRGAVSEKDA SEQ ID NO: 10 PKELLDMLARAEREKKGGGVTSPKALEEAPWPPPEGAFVGFVLSRKEPMWADLLAL AAARGGRVHRAPEPYKALRDLKEARGLLAKDLSVLALREGLGLPPGDDPMLLAYLL DPSNTTPEGVARRYGGEWTEEAGERAALSERLFANLWGRLEGEERLLWLYREVERP LSAVLAHMEATGVRLDVAYLRALSLEVAEEIARLEAEVFRLAGHPFNLNSRDQLERV LFDELGLPAIGKTEKTGKRSTSAAVLEALREAHPIVEKILQYRELTKLKSTYIDPLPDLI HPRTGRLHTRFNQTATATGRLSSSDPNLQNIPVRTPLGQRIRRAFIAEEGWLLVALDY SQIELRVLAHLSGDENLIRVFQEGRDIHTETASWMFGVPREAVDPLMRRAAKTINFG VLYGMSAHRLSQELAIPYEEAQAFIERYFQSFPKVRAWIEKTLEEGRRRGYVETLFGR RRYVPDLEARVKSVREAAERMAFNMPVQGTAADLMKLAMVKLFPRLEEMGARML LQVHDELVLEAPKERAEAVARLAKEVMEGVYPLAVPLEVEVGIGEDWLSAKEGIDG RGGGGHHHHHH The DNA sequence encoding the PL-ΔTaq fusion protein ATGATTACGAATTCGAAGAAAAAGAAAAAGAAAAAGCGTAAGAAACGCAAAAA SEQ ID NO: 11 GAAAAAGAAAGGCGGCGGTGTCACTAGTGGCGCAACCGTAAAGTTCAAGTACAA AGGCGAAGAAAAAGAGGTAGACATCTCCAAGATCAAGAAAGTATGGCGTGTGG GCAAGATGATCTCCTTCACCTACGACGAGGGCGGTGGCAAGACCGGCCGTGGTG CGGTAAGCGAAAAGGACGCGCCGAAGGAGCTGCTGCAGATGCTGGAGAAGCAG AAAAAGGGCGGCGGTGTCACCAGTCCCAAGGCCCTGGAGGAGGCCCCCTGGCCC CCGCCGGAAGGGGCCTTCGTGGGCTTTGTGCTTTCCCGCAAGGAGCCCATGTGGG CCGATCTTCTGGCCCTGGCCGCCGCCAGGGGGGGCCGGGTCCACCGGGCCCCCG AGCCTTATAAAGCCCTCAGGGACCTGAAGGAGGCGCGGGGGCTTCTCGCCAAAG ACCTGAGCGTTCTGGCCCTGAGGGAAGGCCTTGGCCTCCCGCCCGGCGACGACCC CATGCTCCTCGCCTACCTCCTGGACCCTTCCAACACCACCCCCGAGGGGGTGGCC CGGCGCTACGGCGGGGAGTGGACGGAGGAGGCGGGGGAGCGGGCCGCCCTTTCC GAGAGGCTCTTCGCCAACCTGTGGGGGAGGCTTGAGGGGGAGGAGAGGCTCCTT TGGCTTTACCGGGAGGTGGAGAGGCCCCTTTCCGCTGTCCTGGCCCACATGGAGG CCACGGGGGTGCGCCTGGACGTGGCCTATCTCAGGGCCTTGTCCCTGGAGGTGGC CGAGGAGATCGCCCGCCTCGAGGCCGAGGTCTTCCGCCTGGCCGGCCACCCCTTC AACCTCAACTCCCGGGACCAGCTGGAAAGGGTCCTCTTTGACGAGCTAGGGCTTC CCGCCATCGGCAAGACGGAGAAGACCGGCAAGCGCTCCACCAGCGCCGCCGTCC TGGAGGCCCTCCGCGAGGCCCACCCCATCGTGGAGAAGATCCTGCAGTACCGGG AGCTCACCAAGCTGAAGAGCACCTACATTGACCCCTTGCCGGACCTCATCCACCC CAGGACGGGCCGCCTCCACACCCGCTTCAACCAGACGGCCACGGCCACGGGCAG GCTAAGTAGCTCCGATCCCAACCTCCAGAACATCCCCGTCCGCACCCCGCTTGGG CAGAGGATCCGCCGGGCCTTCATCGCCGAGGAGGGGTGGCTATTGGTGGCCCTG GACTATAGCCAGATAGAGCTCAGGGTGCTGGCCCACCTCTCCGGCGACGAGAAC CTGATCCGGGTCTTCCAGGAGGGGCGGGACATCCACACGGAGACCGCCAGCTGG ATGTTCGGCGTCCCCCGGGAGGCCGTGGACCCCCTGATGCGCCGGGCGGCCAAG ACCATCAACTTCGGGGTCCTCTACGGCATGTCGGCCCACCGCCTCTCCCAGGAGC TAGCCATCCCTTACGAGGAGGCCCAGGCCTTCATTGAGCGCTACTTTCAGAGCTT CCCCAAGGTGCGGGCCTGGATTGAGAAGACCCTGGAGGAGGGCAGGAGGCGGG GGTACGTGGAGACCCTCTTCGGCCGCCGCCGCTACGTGCCAGACCTAGAGGCCC GGGTGAAGAGCGTGCGGGAGGCGGCCGAGCGCATGGCCTTCAACATGCCCGTCC AGGGCACCGCCGCCGACCTCATGAAGCTGGCTATGGTGAAGCTCTTCCCCAGGCT GGAGGAAATGGGGGCCAGGATGCTCCTTCAGGTCCACGACGAGCTGGTCCTCGA GGCCCCAAAAGAGAGGGCGGAGGCCGTGGCCCGGCTGGCCAAGGAGGTCATGG AGGGGGTGTATCCCCTGGCCGTGCCCCTGGAGGTGGAGGTGGGGATAGGGGAGG ACTGGCTCTCCGCCAAGGAGGGCATTGATGGCCGCGGCGGAGGCGGGCATCATC ATCATCATCATTAA The amino acid sequence of PL-ΔTaq fusion protein MITNSKKKKKKKRKKRKKKKKGGGVTSGATVKFKYKGEEKEVDISKIKKVWRVGK SEQ ID NO: 12 MISFTYDEGGGKTGRGAVSEKDAPKELLQMLEKQKKGGGVTSPKALEEAPWPPPEG AFVGFVLSRKEPMWADLLALAAARGGRVHRAPEPYKALRDLKEARGLLAKDLSVL ALREGLGLPPGDDPMLLAYLLDPSNTTPEGVARRYGGEWTEEAGERAALSERLFAN LWGRLEGEERLLWLYREVERPLSAVLAHMEATGVRLDVAYLRALSLEVAEEIARLE AEVFRLAGHPFNLNSRDQLERVLFDELGLPAIGKTEKTGKRSTSAAVLEALREAHPIV EKILQYRELTKLKSTYIDPLPDLIHPRTGRLHTRFNQTATATGRLSSSDPNLQNIPVRTP LGQRIRRAFIAEEGWLLVALDYSQIELRVLAHLSGDENLIRVFQEGRDIHTETASWMF GVPREAVDPLMRRAAKTINFGVLYGMSAHRLSQELAIPYEEAQAFIERYFQSFPKVR AWIEKTLEEGRRRGYVETLFGRRRYVPDLEARVKSVREAAERMAFNMPVQGTAAD LMKLAMVKLFPRLEEMGARMLLQVHDELVLEAPKERAEAVARLAKEVMEGVYPL AVPLEVEVGIGEDWLSAKEGIDGRGGGGHHHHHH PRIMER L71F 5′-CCTGCTCTGCCGCTTCACGC-3′ SEQ ID NO: 13 PRIMER L71R 5′-GCACAGCGGCTGGCTGAGGA-3′ SEQ ID NO: 14 PRIMER L18015F 5′-TGACGGAGGATAACGCCAGCAG-3′ SEQ ID NO: 15 PRIMER L23474R 5′-GAAAGACGA TGGGTCGCTAATACGC-3′ SEQ ID NO: 16 PRIMER L18015F 5′-TGACGGAGGATAAC GCCAGCAG-3′ SEQ ID NO: 17 PRIMER L29930R 5′-GGGGTTGGAGGTCAATGGGTTC-3′ SEQ ID NO: 18 PRIMER L30350F 5′-CCTGCTCTGCCGCTTCACGC-3′ SEQ ID NO: 19 PRIMER L35121R 5′-CACATGGTACAGCAAGCCTGGC-3′ SEQ ID NO: 20 PRIMER L2089F 5′-CCCGTATCTGCTGGGA TACTGGC-3 SEQ ID NO: 21 PRIMER L7112R 5′-CAGCGGTGCTGACTGAATCATGG-3 SEQ ID NO: 22 PRIMER L30350F 5′-CCTGCCTGCCGCTTCACGC-3′ SEQ ID NO: 23 PRIMER L40547R 5′-CCAATACCCGTTTCA TCGCGGC-3′ SEQ ID NO: 24 PRIMER H-Amelo-Y 5′-CCACCTCATCCTGG GCACC-3′ SEQ ID NO: 25 PRIMER H-Amelo-YR 5′-GCTTGAGGCCAACCATCAGAGC-3′ SEQ ID NO: 26 Human beta-globin primer 536F 5′-GGTTGGCCAATCTACTCCCAGG-3′ SEQ ID NO: 27 Human beta-globin primer 536R 5′-GCTCACTCAGTGTGGCAAAG-3′ SEQ ID NO: 28 Human beta-globin primer 1408R 5′-GATTAGCAAAAGGGCCTAGCTTGG-3′ SEQ ID NO: 29 The DNA sequence encoding the Sso7d-ΔTaq(Y) protein ATGATTACGAATTCGAGCGCAACCGTAAAGTTCAAGTACAAAGGCGAAGAAAAA SEQ ID NO: 30 GAGGTAGACATCTCCAAGATCAAGAAAGTATGGCGTGTGGGCAAGATGATCTCC TTCACCTACGACGAGGGCGGTGGCAAGACCGGCCGTGGTGCGGTAAGCGAAAAG GACGCGCCGAAGGAGCTGCTGCAGATGCTGGAGAAGCAGAAAAAGGGCGGCGG TGTCACTAGTCCCAAGGCCCTGGAGGAGGCCCCCTGGCCCCCGCCGGAAGGGGCC TTCGTGGGCTTTGTGCTTTCCCGCAAGGAGCCCATGTGGGCCGATCTTCTGGCCCT GGCCGCCGCCAGGGGGGGCCGGGTCCACCGGGCCCCCGAGCCTTATAAAGCCCT CAGGGACCTGAAGGAGGCGCGGGGGCTTCTCGCCAAAGACCTGAGCGTTCTGGC CCTGAGGGAAGGCCTTGGCCTCCCGCCCGGCGACGACCCCATGCTCCTCGCCTAC CTCCTGGACCCTTCCAACACCACCCCCGAGGGGGTGGCCCGGCGCTACGGCGGG GAGTGGACGGAGGAGGCGGGGGAGCGGGCCGCCCTTTCCGAGAGGCTCTTCGCC AACCTGTGGGGGAGGCTTGAGGGGGAGGAGAGGCTCCTTTGGCTTTACCGGGAG GTGGAGAGGCCCCTTTCCGCTGTCCTGGCCCACATGGAGGCCACGGGGGTGCGC CTGGACGTGGCCTATCTCAGGGCCTTGTCCCTGGAGGTGGCCGAGGAGATCGCCC GCCTCGAGGCCGAGGTCTTCCGCCTGGCCGGCCACCCCTTCAACCTCAACTCCCG GGACCAGCTGGAAAGGGTCCTCTTTGACGAGCTAGGGCTTCCCGCCATCGGCAA GACGGAGAAGACCGGCAAGCGCTCCACCAGCGCCGCCGTCCTGGAGGCCCTCCG CGAGGCCCACCCCATCGTGGAGAAGATCCTGCAGTACCGGGAGCTCACCAAGCT GAAGAGCACCTACATTGACCCCTTGCCGGACCTCATCCACCCCAGGACGGGCCG CCTCCACACCCGCTTCAACCAGACGGCCACGGCCACGGGCAGGCTAAGTAGCTC CGATCCCAACCTCCAGAACATCCCCGTCCGCACCCCGCTTGGGCAGAGGATCCGC CGGGCCTTCATCGCCGAGGAGGGGTGGCTATTGGTGGCCCTGGACTATAGCCAG ATAGAGCTCAGGGTGCTGGCCCACCTCTCCGGCGACGAGAACCTGATCCGGGTCT TCCAGGAGGGGCGGGACATCCACACGGAGACCGCCAGCTGGATGTTCGGCGTCC CCCGGGAGGCCGTGGACCCCCTGATGCGCCGGGCGGCCAAGACCATCAAC TAC G GGGTCCTCTACGGCATGTCGGCCCACCGCCTCTCCCAGGAGCTAGCCATCCCTTA CGAGGAGGCCCAGGCCTTCATTGAGCGCTACTTTCAGAGCTTCCCCAAGGTGCGG GCCTGGATTGAGAAGACCCTGGAGGAGGGCAGGAGGCGGGGGTACGTGGAGAC CCTCTTCGGCCGCCGCCGCTACGTGCCAGACCTAGAGGCCCGGGTGAAGAGCGT GCGGGAGGCGGCCGAGCGCATGGCCTTCAACATGCCCGTCCAGGGCACCGCCGC CGACCTCATGAAGCTGGCTATGGTGAAGCTCTTCCCCAGGCTGGAGGAAATGGG GGCCAGGATGCTCCTTCAGGTCCACGACGAGCTGGTCCTCGAGGCCCCAAAAGA GAGGGCGGAGGCCGTGGCCCGGCTGGCCAAGGAGGTCATGGAGGGGGTGTATCC CCTGGCCGTGCCCCTGGAGGTGGAGGTGGGGATAGGGGAGGACTGGCTCTCCGC CAAGGAGGGCATTGATGGCCGCGGCGGAGGCGGGCATCATCATCATCATCATTAA The amino acid sequence of Sso7d-ΔTaq(Y) protein MITNSSATVKFKYKGEEKEVDISKIKKVWRVGKMISFTYDEGGGKTGRGAVSEKDA SEQ ID NO: 31 PKELLQMLEKQKKGGGVTSPKALEEAPWPPPEGAFVGFVLSRKEPMWADLLALAA ARGGRVHRNPEPYKALRDLKEARGLLAKDLSVLALREGLGLPPGDDPMLLAYLLDP SNTTPEGVARRYGGEWTEEAGERAALSERLFANLWGRLEGEERLLWLYREVERPLS AVLAHMEATGVRLDVAYLRALSLEVAEEIARLEAEVFRLAGHPFNLNSRDQLERVLF DELGLPAIGKTEKTGKRSTSAAVLEALREAHPIVEKILQYRELTKLKSTYIDPLPDLIH PRTGRLHTRFNQTATATGRLSSSDPNLQNIPVRTPLGQRIRRAFIAEEGWLLVALDYS QIELRVLAHLSGDENLIRVFQEGRDIHTETASWMFGVPREAVDPLMRRAAKTIN Y GV LYGMSAHRLSQELAIPYEEAQAFIERYFQSFPKVRAWIEKTLEEGRRRGYVETLFGRR RYVPDLEARVKSVREAAERMAFNMPVQGTAADLMKLAMVKLFPRLEEMGARMLL QVHDELVLEAPKERAEAVARLAKEVMEGVYPLAVPLEVEVGIGEDWLSAKEGIDGR GGGGHHHHHH The DNA sequence encoding the Sso7d-ΔTaq (E5)(Y) protein ATGATTACGAATTCGAGCGCAACCGTAAAGTTCAAGTACAAAGGCGAAGAAAAA SEQ ID NO: 32 GAGGTAGACATCTCCAAGATCAAGAAAGTATGGCGTGTGGGCAAGATGATCTCC TTCACCTACGACGAGGGCGGTGGCAAGACCGGCCGTGGTGCGGTAAGCGAAAAG GACGCGCCGAAGGAGCTGCTGCAGATGCTGGAGAAGCAGAAAAAGGGCGGCGG TGTCACTAGTGGGATGCTGCCCCTCTTTGAGCCCAAGGGCCGGGTCCTCCTGGTG GACGGCCACCACCTGGCCTACCGCACCTTCCACGCCCTGAAGGGCCTCACCACCA GCCGGGGGGAGCCGGTGCAGGCGGTCTACGGCTTCGCCAAGAGCCTCCTCAAGG CCCTCAAGGAGGACGGGGACGCGGTGATCGTGGTCTTTGACGCCAAGGCCCCCT CCTTCCCCCACGAGGCCTACGGGGGGCACAAGGCGGGCCGGGCCCCCACGCCAG AGGACTTTCCCCGGCAACTCGCCCTCATCAAGGAGCTGGTGGACCTCCTGGGGCT GGCGCGCCTCGAGGTCCCGGGCTACGAGGCGGACGACGTCCTGGCCAGCCTGGC CAAGAAGGCGGAAAAGGAGGGCTACGAGGTCCGCATCCTCACCGCCGACAAAG ACCTTTACCAGCTCCTTTCCGACCGCATCCACGTCCTCCACCCCGAGGGGTACCT CATCACCCCGGCCTGGCTTTGGGAAAAGTACGGCCTGAGGCCCGACCAGTGGGC CGACTACCGGGCCCTGACCGGGGACGAGTCCGACAACCTTCCCGGGGTCAAGGG CATCGGGGAGAAGACGGCGAGGAAGCTTCTGGAGGAGTGGGGGAGCCTGGAAG CCCTCCTCAAGAACCTGGACCGGCTGAAGCCCGCCATCCGGGAGAAGATCCTGG CCCACATGGACGATCTGAAGCTCTCCTGGGACCTGGCCAAGGTGCGCACCGACCT GCCCCTGGAGGTGGACTTCGCCAAAAGGCGGGAGCCCGACCGGGAGAGGCTTAG GGCCTTTCTGGAGAGGCTTGAGTTTGGCAGCCTCCTCCACGAGTTCGGCCTTCTG GAAAGCCCCAAGGCCCTGGAGGAGGCCCCCTGGCCCCCGCCGGAAGGGGCCTTC GTGGGCTTTGTGCTTTCCCGCAAGGAGCCCATGTGGGCCGATCTTCTGGCCCTGG CCGCCGCCAGGGGGGGCCGGGTCCACCGGGCCCCCGAGCCTTATAAAGCCCTCA GGGACCTGAAGGAGGCGCGGGGGCTTCTCGCCAAAGACCTGAGCGTTCTGGCCC TGAGGGAAGGCCTTGGCCTCCCGCCCGGCGACGACCCCATGCTCCTCGCCTACCT CCTGGACCCTTCCAACACCACCCCCGAGGGGGTGGCCCGGCGCTACGGCGGGGA GTGGACGGAGGAGGCGGGGGAGCGGGCCGCCCTTTCCGAGAGGCTCTTCGCCAA CCTGTGGGGGAGGCTTGAGGGGGAGGAGAGGCTCCTTTGGCTTTACCGGGAGGT GGAGAGGCCCCTTTCCGCTGTCCTGGCCCACATGGAGGCCACGGGGGTGCGCCT GGACGTGGCCTATCTCAGGGCCTTGTCCCTGGAGGTGGCCGAGGAGATCGCCCG CCTCGAGGCCGAGGTCTTCCGCCTGGCCGGCCACCCCTTCAACCTCAACTCCCGG GACCAGCTGGAAAGGGTCCTCTTTGACGAGCTAGGGCTTCCCGCCATCGGCAAG ACGGAGAAGACCGGCAAGCGCTCCACCAGCGCCGCCGTCCTGGAGGCCCTCCGC GAGGCCCACCCCATCGTGGAGAAGATCCTGCAGTACCGGGAGCTCACCAAGCTG AAGAGCACCTACATTGACCCCTTGCCGGACCTCATCCACCCCAGGACGGGCCGCC TCCACACCCGCTTCAACCAGACGGCCACGGCCACGGGCAGGCTAAGTAGCTCCG ATCCCAACCTCCAGAACATCCCCGTCCGCACCCCGCTTGGGCAGAGGATCCGCCG GGCCTTCATCGCCGAGGAGGGGTGGCTATTGGTGGCCCTGGACTATAGCCAGAT AGAGCTCAGGGTGCTGGCCCACCTCTCCGGCGACGAGAACCTGATCCGGGTCTTC CAGGAGGGGCGGGACATCCACACGGAGACCGCCAGCTGGATGTTCGGCGTCCCC CGGGAGGCCGTGGACCCCCTGATGCGCCGGGCGGCCAAGACCATCAACTACGGG GTCCTCTACGGCATGTCGGCCCACCGCCTCTCCCAGGAGCTAGCCATCCCTTACG AGGAGGCCCAGGCCTTCATTGAGCGCTACTTTCAGAGCTTCCCCAAGGTGCGGGC CTGGATTGAGAAGACCCTGGAGGAGGGCAGGAGGCGGGGGTACGTGGAGACCC TCTTCGGCCGCCGCCGCTACGTGCCAGACCTAGAGGCCCGGGTGAAGAGCGTGC GGGAGGCGGCCGAGCGCATGGCCTTCAACATGCCCGTCCAGGGCACCGCCGCCG ACCTCATGAAGCTGGCTATGGTGAAGCTCTTCCCCAGGCTGGAGGAAATGGGGG CCAGGATGCTCCTTCAGGTCCACGACGAGCTGGTCCTCGAGGCCCCAAAAGAGA GGGCGGAGGCCGTGGCCCGGCTGGCCAAGGAGGTCATGGAGGGGGTGTATCCCC TGGCCGTGCCCCTGGAGGTGGAGGTGGGGATACGGGAGGACTGGCTCTCCGCCA AGGAGGGCATTGATGGCCGCGGCGGAGGCGGGCATCATCATCATCATCATTAA The amino acid sequence of Sso7d-ΔTaq (E5)(Y) protein MITNSSATVKFKYKGEEKEVDISKIKKVWRVGRMISFTYDEGGGKTGRGAVSEKDA SEQ ID NO: 33 PKELLQMLEKQKKGGGVTSGMLPLFEPKGRVLLVDGHHLAYRTFHALKGLTTSRGE PVQAVYGFAKSLLKALREDGDAVIVVFDAKAPSFPHEAYGGHKAGRAPTPEDFPRQ LALIKELVDLLGLARLEVPGYEADDVLASLAKKAEKEGYEVRILTADKDLYQLLSDR IHVLHPEGYLITPAWLWEKYGLRPDQWADYRALTGDESDNLPGVKGIGEKTARKLL EEWGSLEALLKNLDRLKPAIREKILAHMDDLKLSWDLAKVRTDLPLEVDFAKRREP DRERLRFLERLEFGSLLHEFGLLESPKALEEAPWPPPEGAFVGFVLSKEPMWADL LALAAARGGRVHRAPEPYKALRDLKEARGLLAKDLSVLALREGLGLPPGDDPMLLA YLLDPSNTTPEGVARRYGGEWTEEAGERAALSERLFANLWGRLEGEERLLWLYREV ERPLSAVLAHMEATGVRLDVAYLRALSLEVAEEIARLEAEVFRLAGHPFNLNSRDQL ERVLFDELGLPAIGKTEKTGKRSTSAAVLEALREAHPIVEKILQYRELTKLKSTYIDPL PDLIHPRTGRLHTRFNQTATATGRLSSSDPNLQNIPVRTPLGQRIRRAFIAEEGWLLVA LDYSQIELRVLAHLSGDENLIRVFQEGRDIHTETASWMFGVPREAVDPLMRRAAKTI NYGVLYGMSAHRLSQELAIPYEEAQAFIERYFQSFPKVRAWIEKTLEEGRRRGYVET LFGRRRYVPDLEARVKSVREAAERMAFNMPVQGTAADLMKLAMVKLFPRLEEMG ARMLLQVHDELVLEAPKERAEAVARLAKEVMEGVYPLAVPLEVEVGIGEDWLSAK EGIDGRGGGGHHHHHH peptide linker Gly-Gly-Val-Thr SEQ ID NO: 34 peptide linker Gly-Thr-Gly-Gly-Gly-Gly SEQ ID NO: 35 lysine-rich peptide NSKKKKKKKRKKRKKKGGGVT SEQ ID NO: 36 

1. A method of performing a quantitative real-time polymerase chain reaction on a target nucleic acid present in a solution that comprises a DNA-binding fluorescent dye, the method comprising: (a) contacting the target nucleic acid with a DNA polymerase, wherein the DNA polymerase is joined to a sequence non-specific double-stranded nucleic acid binding domain that comprises at least 75% amino acid sequence identity to the Sso7d amino acid sequence set forth in SEQ ID NO:2 and enhances the processivity of the DNA polymerase compared to an identical DNA polymerase not having the sequence non-specific double-stranded nucleic-acid binding domain fused to it, wherein the solution comprises the DNA-binding fluorescent dye, which exhibits altered fluorescence emissions when the dye is bound to double-stranded DNA, and is of a composition that permits the sequence non-specific double-stranded nucleic acid binding domain to bind to the target nucleic acid and the polymerase domain to extend a primer that is hybridized to the target nucleic acid sequence; (b) incubating the solution under conditions in which the primer is extended by the DNA polymerase; (c) exposing the solution to a suitable excitation light and measuring fluorescence emission from the DNA-binding fluorescent dye; and (d) performing at least one additional cycle of amplification comprising steps (a) to (c).
 2. The method of claim 1, wherein the polymerase domain has thermally stable activity.
 3. The method of claim 2, wherein the polymerase domain comprises a ΔTaq polymerase domain.
 4. The method of claim 2, wherein the polymerase domain comprises a Pyrococcus polymerase domain.
 5. The method of claim 1, wherein the sequence non-specific double-stranded nucleic acid binding domain comprises at least 90% amino acid sequence identity to the amino acid sequence of SEQ ID NO:2.
 6. The method of claim 1, wherein the sequence non-specific double-stranded nucleic acid binding domain comprises the amino acid sequence set forth in SEQ ID NO:2, or Sac7d.
 7. The method of claim 1, wherein the dye is SYBR Green I. 